Identification of chemically modified polymers

ABSTRACT

The present invention provides a high-throughput method for the parallel analysis of many potential sites of chemical modification (e.g., methylation) in DNA. It makes use of chemical treatment of the DNA to alter its sequence in a way that depends upon the modification of interest and subsequent analysis of the resulting sequence by hybridization to an array of probes. A device, comprising the array of probes, is provided by the invention, and principles and methods for its design and fabrication are also provided.

[0001] This application claims priority to U.S. Provisional Patent Application Serial No. 60/301,370 filed Jun. 27, 2001.

[0002] The U.S. Government may own certain rights in this invention pursuant to the terms of the National Cancer Institute grant CA81656-01.

FIELD OF THE INVENTION

[0003] The present invention relates generally to the analysis of chemically modified macromolecules, and specifically to the detection of modified sites in DNA with the use of oligonucleotide arrays.

BACKGROUND OF THE INVENTION

[0004] Methylation of cytosines in CpG dinucleotides is an important mechanism of transcriptional regulation. It is involved in a variety of normal biological processes such as X chromosome inactivation and transcriptional regulation of imprinted genes. Aberrant methylation of cytosines can also effect transcriptional inactivation of certain tumor suppressor genes, associated with a number of human cancers. Cytosine methylation in CpG-rich areas (CpG islands) located in the promoter regions of some genes is of special regulatory importance. Therefore, wide scope mapping of methylation sites in CpG islands is important for understanding both normal and pathological cellular processes. Furthermore, methylation of certain sites may serve as an important marker for early diagnosis and treatment decisions of some cancers.

[0005] A variety of methods have been used to identify sites of DNA methylation. One common method has relied on the inability of restriction endonucleases to cleave sequences that contain one or more methylated cytosines. Genomic DNA is fragmented with appropriate restriction enzymes and cleavage at the site of interest is probed electrophoretically or by PCR. This method provides an analysis of some potential methylation sites, but it is limited to sites that fall within the recognition sequences of methylation-sensitive restriction enzymes.

[0006] Other methods rely on the differential chemical reactivities of cytosine and 5-methyl cytosine with reagents such as sodium bisulfite, hydrazine, or permanganate. In the case of hydrazine and permanganate, differential strand cleavage between methylated and unmethylated cytosines is examined in a similar fashion to that used when cleavage is done with restriction enzymes. This approach is complicated by the imperfect specificity of the reagents between methylated and unmethylated cytosines and by interference from reaction with thymidines.

[0007] Treatment with sodium bisulfite can be used to convert methylated and unmethylated DNA to different sequences. Under appropriate conditions, unmethylated cytosines in DNA react with sodium bisulfite to yield deoxyuridine, which behaves as thymidine in Watson-Crick hybridization and enzymatic template-directed polymerization. Methylated cytosines, however, are unreactive, and behave as cytosine in Watson-Crick hybridization and enzymatic template-directed polymerization.

[0008] The sequence differences resulting from bisulfite treatment can be assessed in any of several ways. One way is with standard sequencing by primer extension (Sanger sequencing). This method has the disadvantage of limited throughput. Another way, termed methylation-specific PCR, uses a set of PCR primers specific to the sequences resulting from bisulfite treatment of either methylation state at a given site. Effective amplification using one primer from the set indicates methylation, whereas effective amplification using the other primer indicates unmethylated cytosine at the site being amplified. This method has the disadvantage of low sample throughput in addition to the disadvantage that only one potential site of methylation is probed in an assay.

[0009] Thus, there is a need for a high throughput method for the identification of alteration in DNA.

SUMMARY OF THE INVENTION

[0010] The present invention provides a high-throughput method for the parallel analysis of many potential sites of chemical modification (e.g., methylation) in DNA. It makes use of chemical treatment of the DNA to alter its sequence in a way that depends upon the modification of interest and subsequent analysis of the resulting sequence by hybridization to an array of probes. A device, comprising the array of probes, is provided by the invention, and principles and methods for its design and fabrication are also provided.

[0011] In one form the present is a method for the analysis of chemical modification of DNA including the steps of obtaining a sample of DNA to be analyzed and treating the DNA with one or more chemical reagents that result in different base sequences depending upon the presence or absence of the modification of interest, and determining a portion of the base sequence of the resulting DNA.

[0012] Another form of the present invention is an array of one or more nucleic acid probes immobilized on a solid support wherein the probes are designed to detect sites of methylation in DNA.

[0013] Yet another form of the invention is a method for generating DNA probe sequences that includes the steps of inputting a nucleic acid sequence in the 3-prime to 5-prime direction and converting the sequence to account for chemical modification. The complementary sequence to the converted sequence in the 3-prime to 5-prime direction is then generated. A first parent probe is then generated by choosing a first starting position on the complementary sequence and a first ending position on the complementary sequence. A second parent probe is then generated by moving the first starting and first ending position one base unit in the same direction. This process may be repeated as often as desired.

[0014] Another form of the resent invention is a method for generating DNA probe sequences that includes the steps of inputting a nucleic acid sequence in the 3-prime to 5-prime direction and converting the sequence to account for chemical modification. The complementary sequence to the converted sequence in the 3-prime to 5-prime direction is then generated. The complementary sequence is then examined to locate one or more CpG dinucleotide regions within the complementary sequence, and probes are then generated that have one or more nucleic acid bases on each end of the CpG dinucleotide regions.

BRIEF DESCRIPTION OF THE FIGURES

[0015] The above and further advantages of the invention may be better understood by referring to the following detailed description in conjunction with the accompanying drawings in which corresponding numerals in the different FIGURES refer to the corresponding parts in which:

[0016]FIG. 1 depicts a reaction in accordance with the present invention;

[0017]FIG. 2 depicts a method of re-sequencing in accordance with the present invention;

[0018]FIG. 3 depicts a schematic of assay results in accordance with the present invention;

[0019]FIG. 4 depicts the results of a two-color assay in accordance with the present invention;

[0020]FIG. 5 depicts a fluorescence scan in accordance with the present invention;

[0021]FIG. 6 depicts an assay for CpG methylation by (A) treatment with sodium bisulfite to convert unmethylated cytosines to deoxyuracils (4 cytosines) while methylated cytosines remain unconverted (one cytosine denoted as methylated with a superscript Me) and (B) sequence analysis of a labeled representative of the bisulfite-treated DNA by hybridization to an array of oligonucleotides in accordance with the present invention;

[0022]FIG. 7 depicts the sequence of the 190 base region of the p16 promoter wherein each cytosine in the sequence is numbered in accordance with the present invention;

[0023]FIG. 8 depicts four probes from an array used to analyze the methylation state of a region of the promoter for p16 showing (A) fluorescence scan of the Cy5 (analyte) channel of the array, (B) fluorescence scan of the Cy3 (reference) channel of the array, (C) overlay of the analyte and reference channels demonstrating the appearance of a methylated site compared with an unmethylated reference in accordance with the present invention; and

[0024]FIG. 9 is a histogram plots showing Z scores for each cytosine in a CpG dinucleotide using analysis in which the analyte was derived from (A) uniformly methylated DNA, (B) a synthetic duplex simulating unique methylation at cytosine number 25, (C) a mixture of approximately 20% methylated DNA and 80% unmethylated DNA in accordance with the present invention.

DETAILED DESCRIPTION

[0025] While the making and using of various embodiments of the present invention are discussed herein in terms of identification of methylated sites in DNA, it should be appreciated that the present invention provides many applicable inventive concepts that can be embodied in a wide variety of specific contexts. The specific embodiments discussed herein are merely illustrative of specific ways to make and use the invention and are not meant to limit the scope of the invention in any manner.

[0026] The need for high-throughput methods is highlighted by the prevalence of CpG islands in the genome. Computer analysis of the March 2001 Unigene build reveals 32,597 of the 92,152 clusters contain CpG islands. Of the 14,968 clusters with annotation, 10,438 have CpG islands. These islands in the annotated clusters comprise 4,398,560 bp in 5′ non-coding regions, 7,074,411 bp in coding regions, and 492,323 bp in 3′ non-coding regions. A high throughput method of the present invention will be necessary to interrogate even a small fraction of these sites in a given experiment.

[0027] The differential reactivity of bisulfite with cytosine and 5-methylcytosine forms the basis of several techniques for the assessment of DNA methylation; however, new approaches to the read-out of the sequence that results from treatment with bisulfite are desirable. Sequence analysis by hybridization to oligonucleotide arrays is an approach that affords a high degree of parallelism and flexibility. The present invention relies on discrimination between a cytosine and a thymidine in the array hybridization.

[0028] All technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless defined otherwise. Methods and materials similar or equivalent to those described herein may be used in the practice or testing of the present invention, the generally used methods and materials are now described.

[0029] Definitions

[0030] To facilitate the understanding of this invention, a number of terms are defined below. Terms defined herein have meanings as commonly understood by a person of ordinary skill in the areas relevant to the present invention. Terms such as “a”, “an” and “the” are not intended to refer to only a singular entity, but include the general class of which a specific example may be used for illustration. The terminology herein is used to describe specific embodiments of the invention, but their usage does not limit the invention, except as outlined in the claims.

[0031] As used throughout the present specification the following abbreviations are used: TF, transcription factor; ORF, open reading frame; kb, kilobase (pairs); UTR, untranslated region; kD, kilodalton; PCR, polymerase chain reaction; RT, reverse transcriptase.

[0032] The term “homology” refers to the extent to which two nucleic acids are complementary. There may be partial or complete homology. A partially complementary sequence is one that at least partially inhibits a completely complementary sequence from hybridizing to a target nucleic acid and is referred to using the functional term “substantially homologous.” The degree or extent of hybridization may be examined using a hybridization or other assay (such as a competitive PCR assay) and is meant, as will be known to those of skill in the art, to include specific interaction even at low stringency.

[0033] The art knows that numerous equivalent conditions may be employed to achieve low stringency conditions. Factors that affect the level of stringency include: the length and nature (DNA, RNA, base composition) of the probe and nature of the target (DNA, RNA, base composition, present in solution or immobilized, etc.) and the concentration of the salts and other components (e.g., formamide, dextran sulfate, polyethylene glycol). Likewise, the hybridization solution may be varied to generate conditions of low stringency hybridization different from, but equivalent to, the above listed conditions. In addition, the art knows conditions that promote hybridization under conditions of high stringency (e.g., increasing the temperature of the hybridization and/or wash steps, inclusion of formamide, etc.).

[0034] The term “gene” is used to refer to a functional protein, polypeptide or peptide-encoding unit. As will be understood by those in the art, this functional term includes genomic sequences, cDNA sequences, or fragments or combinations thereof, as well as gene products, including those that may have been altered by the hand of man. Purified genes, nucleic acids, protein and the like are used to refer to these entities when identified and separated from at least one contaminating nucleic acid or protein with which it is ordinarily associated.

[0035] The term “portion of a genome for genetic analysis” or “chromosome-specific” is herein defined to encompass the terms “target specific” and “region specific”, that is, when the staining composition is directed to one chromosome or portion of a genome, it is chromosome-specific, but it is also chromosome-specific when it is directed, for example, to multiple regions on multiple chromosomes, or to a region of only one chromosome, or to regions across the entire genome. Likewise, “locus specific” or “loci specific” is defined as locations on one or more chromosomes for a particular gene or allele. Sequence from regions of one or more chromosomes are sources for probes for that region or those regions of the genome. The probes produced from such source material are region-specific probes but are also encompassed within the broader phrase “portion of a genome” probes. The term “target specific” is interchangeably used herein with the term “chromosome-specific” and “portion of a genome”.

[0036] The word “specific” as commonly used in the art has two somewhat different meanings. The practice is followed herein. “Specific” refers generally to the origin of a nucleic acid sequence or to the pattern with which it will hybridize to a genome, e.g., as part of a staining reagent. For example, isolation and cloning of DNA from a specified chromosome results in a “chromosome-specific library.” Shared sequences are not chromosome-specific to the chromosome from which they were derived in their hybridization properties since they will bind to more than the chromosome of origin. A sequence is “locus specific” if it binds only to the desired portion of a genome. Such sequences include single-copy sequences contained in the target or repetitive sequences, in which the copies are contained predominantly in the selected sequence.

[0037] A “probe” as defined herein may be one or more molecules that can hybridize to a nucleic acid target sequence and that can be detected (e.g., nucleic acid fragments or other oligomers that bind nucleic acids). Examples of possible probe molecules include, but are not limited to, DNA, RNA, peptides, minor groove-binding polyamides, peptide nucleic acids (PNA), locked nucleic acids (LNA), and 2′-O-methyl nucleic acids. The probe is labeled so that its binding to the target can be assayed, visualized or detected. In essence the probe is designed to bind a target, also referred to as an analyte, so that the combination of probe and analyte may be assayed, visualized or detected. The probe may be produced from some source of nucleic acid sequences, for example, a collection of clones or a collection of polymerase chain reaction (PCR) products or the product of nick translation or other methods for adding a detectable marker to a nucleic acid binding moiety. For nucleic acids, repetitive sequences are removed or blocked with unlabeled nucleic acid with complementary sequence, so that hybridization with the resulting probe produces staining of sufficient contrast on the target. The word probe may be used herein to refer not only to a molecule that detects a nucleic acid, but also to the detectable nucleic acid in the form in which it is applied to, e.g., the surface of an array. What “probe” refers to specifically should be clear to those of skill in the art from the context in which the word is used.

[0038] The term “labeled” as used herein indicates that there is some method to visualize or detect the bound probe, whether or not the probe directly carries some modified constituent. The terms “staining” or “painting” are herein defined to mean hybridizing a probe of this invention to a genome or segment thereof, such that the probe reliably binds to the targeted region or sequence of chromosomal material and the bound probe is capable of being detected. The terms “staining” or “painting” are used interchangeably. The patterns on the array resulting from “staining” or “painting” are useful for cytogenetic analysis, more particularly, molecular cytogenetic analysis. The staining patterns facilitate the high-throughput identification of normal and abnormal chromosomes and the characterization of the genetic nature of particular abnormalities.

[0039] Multiple methods of probe detection may be used with the present invention, e.g., the binding patterns of different components of the probe may be distinguished, for example, by color or differences in wavelength emitted from a labeled probe.

[0040] A number of different aberrations may be detected with any desired staining pattern on the portions of the genome detected with one or more colors (a multi-color staining pattern) and/or other indicator methods.

[0041] The complexity for a final probe list and array will depend on the application for which it is designed (e.g., location on the genome, complexity of the sequence, etc.) and the mapping resolution that is sought. In general, the larger the target area, the more complex the probe list. The term “complexity” therefore refers to the complexity of the total probe list no matter how many visually distinct loci are to be detected, that is, regardless of the distribution of the target sites over the genome.

[0042] The required contrast (e.g., signal to noise) for detection will depend on the application for which the probe is designed and even the portion of the genome that is the target of the analysis. When visualizing chromosomes and nuclei, etc., microscopically, a contrast ratio of two or greater is often sufficient for identifying whole chromosomes. When quantifying the amount of target region present on an array by fluorescence intensity measurements using a slide reader or quantitative microscopy.

[0043] Identification of a large number of individual methylation sites in a high-throughput, highly parallel assay can be accomplished by specifically converting only unmethylated cytosines to deoxyuridines with sodium bisulfite treatment, as shown in FIG. 1, and rapidly reading out the resulting sequence. Any cytosine remaining in the product is identified as a site of methylation. Oligonucleotide arrays are particularly well suited to rapidly distinguishing between closely related nucleic acid sequences with a method known as re-sequencing.

[0044] The method of re-sequencing is depicted in FIG. 2. A sequence of interest is shown in FIG. 2A, where an unknown base is at a central position, identified in the FIGURE with an N. FIG. 2B shows four oligonucleotide probes used to assay each base position of interest, each probe complementary to the sequence being tested except at the position of the unknown base. At the position of the unknown base, the probes differ, each having a different one of the four possible bases. The probe oligonucleotides may be immobilized on a surface as shown in FIG. 2, but other formats are possible. FIG. 2C shows the DNA to be tested binding to one of the four probes. It binds specifically to the probe with an adenosine in the test position, identifying the unknown base, N, as a thymidine. Specificity is highest when the probed base binds near the center of probe oligonucleotide.

[0045] In practice, re-sequencing with oligonucleotide arrays can be accomplished by a number of means, any of which will be applicable to the present invention. In one standard approach, the array of oligonucleotides is immobilized on a glass surface. An example of a “feature” of the resulting array is defined as a region of the surface in which a single probe sequence predominates. Fabrication of surface-bound oligonucleotide arrays can also be accomplished by a variety of methods known to those with skill in the art.

[0046] A fabrication method that is particularly appropriate for the present invention makes use of light directed chemistry to synthesize the oligonucleotides directly on the surface. The regions of the surface that are illuminated during pre-determined chemical steps of the synthesis determine the sequence synthesized in each feature. Defined regions can be illuminated discretely by, for example, shining light through a physical mask that blocks light from particular regions or by directing light to particular regions with a digital micromirror array. These light-directed approaches are desirable for the present invention, because they currently enable the largest numbers of features per unit area of array surface. Thus, the potential of the current invention for highly parallel analysis of methylation is best met by the very high feature numbers accessible with light-directed methods. However, other methods of array fabrication are amenable to the present invention, including but not limited to delivering the reagents of DNA synthesis to specific regions of the surface and depositing on the surface oligonucleotides that have been pre-synthesized.

[0047] Typically, a solution of the nucleic acid to be analyzed is applied to the surface of the array, and the dissolved nucleic acid is allowed to bind to probes on the surface. After an appropriate time, the unbound and the weakest bound nucleic acid are washed from the array and the bound nucleic acid is detected. Detection of binding can be accomplished in several ways known to those of skill in the art, any of which can be applied to the present invention. In one method, detection is accomplished by labeling the test nucleic acid with a moiety such as a fluorophore and measuring fluorescence associated with each probe. FIG. 2D schematically illustrates the appearance of a fluorescence scan of four features designed to probe a single base following binding and washing. The brightest feature indicates the identity of the probed base position. Many methods are also known for the incorporation of a fluorescent label into a test nucleic acid, including but not limited to nick translation, transcription into RNA using a template-directed RNA polymerase to incorporate labeled nucleotide triphosphates, or amplifying a region of interest with PCR using labeled primers.

[0048] In operation, the present invention may be used, for example, as described herein. A sample of genomic DNA to be analyzed is obtained and treated with bisulfite under conditions for which that reaction converts unmethylated cytosines to deoxyuridines but does not effect methylated cytosines. One or more regions of interest from the resulting DNA are then amplified by PCR and labeled by any of a variety of methods. Design of primers for PCR amplification of bisulfite-treated DNA should be guided by the following considerations: 1) the primers should not contain CpG dinucleotides of unknown methylation state, 2) the primers are restricted to a three-base code (A, G, and T) because all cytosines not in CpG dinucleotides are converted to deoxyuridine, 3) some bisulfite treatment protocols, such as the one described below, cleave the DNA substantially, so amplification of short regions (about 200 base pairs) is most successful, and 4) a different set of primers is required for each strand, because the two initially complementary strands are no longer complementary after bisulfite treatment.

[0049] A solution of the labeled nucleic acid is then contacted with an array of probes comprising probes that bind differentially to the sequences resulting from bisulfite treatment of methylated or unmethylated cytosines of interest. In practice, such probes can be made by creating oligonucleotides that are complementary to a region of DNA surrounding the cytosine of interest, taking into account the conversion of all cytosines not in a CpG dinucleotide to deoxyuridine, which is complementary to adenosine. A typical length for such oligonucleotide probes is between 15 and 30 nucleotides, but longer and shorter probes are possible. The site to be probed should be near the center of the region to which the probe is complementary.

[0050] At least two probes are required for each potential methylation site of interest. In one, the base in apposition to the site to be probed is an adenosine, forming the complement to the deoxyuridine-containing sequence corresponding to the unmethylated state. In the other, the base at the same position is guanosine, forming the complement to the cytosine-containing sequence corresponding to the methylated state. Although methylation state can be determined with these two probes only, it is preferable to use four probes for every site, one with each of the four bases at he variable position, in order to account for the possibility of polymorphism or mutation at the site of interest. Possible results of this assay are shown schematically in FIG. 3. FIG. 3A illustrates a result indicating methylation of the site of interest, the brightest feature being that corresponding to cytosine. FIG. 3B illustrates a result indicating absence of methylation at the site of interest, the brightest feature being that corresponding to thymidine. FIG. 3C illustrates a result indicating polymorphism or mutation at the site of interest to an adenosine.

[0051] Multiple CpG dinucleotides of unknown methylation state will often be sufficiently proximal to each other in sequences to be analyzed that the probe will include one or more CpG dinucleotides in addition to the central one being analyzed. If a methylation state is assumed for these additional sites in the design of the probe sequence, the probe affinity for the analyte will be diminished whenever the assumed methylation state is not the actual methylation state. Including on the array additional probes that accommodate all possible methylation states can compensate for the resulting decrease in signal.

[0052] The array may comprise probes that have been selected by visual inspection of the sequences to be probed or probes that have been selected by automated computational means. Because the present invention is most advantageous when probing a large number of sites in parallel, the preferred method of probe choice is by automated computational means. A process for probe selection is outlined below. Automated searching of genome databases can identify regions of particular interest with a high density of CpG dinucleotides.

[0053] Two or more labels, such as fluorophores with different excitation and emission frequencies, can be used to compare one or more test samples with a reference sample. The reference sample can be a standard of known methylation state, a DNA sample from a reference tissue, such as a healthy tissue proximal to a diseased tissue to be tested, or a sample from the same cellular source as the test sample that has not been treated with bisulfite. The use of a reference sample of known methylation state provides an internal control for expected relative binding to probes, resulting in higher confidence in assignment of methylation state of unknown samples. The use of a reference sample from a reference tissue provides facile identification of methylation that is related to a particular phenotype, such as a disease phenotype. The use of a reference sample from the same cellular source as the test sample provides control for the possibility of a cytosine to thymidine mutation or polymorphism.

[0054] Possible results of a two-color assay with an unmethylated reference sample are shown in FIG. 4. The reference sample is labeled with the red dye, and the sample to be analyzed is labeled with the green dye. FIG. 4A illustrates a result indicating methylation of the site of interest, the brightest green feature being that corresponding to cytosine and the brightest red feature corresponding to thymidine. FIG. 4B illustrates a result indicating absence of methylation at the site of interest, the brightest feature in both data channels being that corresponding to thymidine. FIG. 4C illustrates a result indicating polymorphism or mutation at the site of interest to an adenosine.

[0055] The probes of the array need not be restricted to DNA. Any molecule that binds differentially to the sequences resulting from bisulfite treatment of methylated and unmethylated DNA can be used. Examples of possible probe molecules include, but are not limited to, RNA, peptides, minor groove-binding polyamides, peptide nucleic acids (PNA), locked nucleic acids (LNA), and 2′-O-methyl nucleic acid.

EXAMPLE 1 Analysis of Methylation of a Region of the Promoter for the Tumor Suppressor Gene p16

[0056] Genomic DNA was isolated from two lines of lung tumor cells, H69 and H1618. The promoter region of the tumor suppressor gene P16 is known to be methylated at cytosines in CpG dinucleotides in the line H1618 and is not methylated in the line H69. DNA from both lines was treated with sodium bisulfite as described in the protocol below, which converts unmethylated cytosine to deoxyuridine (essentially equivalent to thymidine in hybridization) but does not react with methylated cytosine. A 145 base pair region from the p16 promoter from each cell line was amplified with labeled primers. Primers labeled with Cy5 were used to amplify the unmethylated promoter (which represents a control or reference sequence) and primers labeled with Cy3 were used to amplify the methylated promoter (which represents the unknown methylation state to be analyzed).

[0057] The two samples were mixed together with the labeled control oligonucleotide and applied to the array. The array, fabricated by light-directed chemistry using a digital micromirror array, had two sets of features in addition to the control features. One set of features (upper half of array) was a standard re-sequencing tiling for the sequence expected without methylation (i.e., all Cs converted to T). The other set was a standard re-sequencing tiling for the sequence expected with methylation of every C in each CpG step. The set of probes used in the array appears as TABLE 1. A two-color fluorescence scan of the array after hybridization for 16 hours at room temperature and washing with 1×SSPE is shown in FIG. 5. Overall methylation state is evident by the labeled sample which binds best to each set of features, the Cy5 labeled, unmethylated sample binding best to the upper tiles for unmethylated sequence (highest signal red) and the Cy3 labeled, methylated sample binding best to the lower tiles for methylated sequence (highest signal green). Specific sites of methylation can be observed by reading sequence directly and by visually identifying columns in which the feature for C is green and the feature for T is red (easily visualized in both sets of probes). TABLE 1 Probes Used in the Array SEQ ID NO Nucleotide Sequence for Probe SEQ ID NO: 1 AACCAACCAATAATCTCCCAC SEQ ID NO: 2 ACCAACCAATTATCTCCCACC SEQ ID NO: 3 CCAACCAATATTCTCCCACCC SEQ ID NO: 4 CAACCAATAATCTCCCACCCC SEQ ID NO: 5 AACCAATAATTTCCCACCCCA SEQ ID NO: 6 ACCAATAATCTCCCACCCCAC SEQ ID NO: 7 CCAATAATCTTCCACCCCACC SEQ ID NO: 8 CAATAATCTCTCACCCCACCT SEQ ID NO: 9 AATAATCTCCTACCCCACCTA SEQ ID NO: 10 ATAATCTCCCTCCCCACCTAA SEQ ID NO: 11 TAATCTCCCATCCCACCTAAC SEQ ID NO: 12 AATCTCCCACTCCACCTAACT SEQ ID NO: 13 ATCTCCCACCTCACCTAACTC SEQ ID NO: 14 TCTCCCACCCTACCTAACTCA SEQ ID NO: 15 CTCCCACCCCTCCTAACTCAC SEQ ID NO: 16 TCCCACCCCATCTAACTCACA SEQ ID NO: 17 CCCACCCCACTTAACTCACAC SEQ ID NO: 18 CCACCCCACCTAACTCACACA SEQ ID NO: 19 CACCCCACCTTACTCACACAA SEQ ID NO: 20 ACCCCACCTATCTCACACAAA SEQ ID NO: 21 CCCCACCTAATTCACACAAAC SEQ ID NO: 22 CCCACCTAACTCACACAAACC SEQ ID NO: 23 CCACCTAACTTACACAAACCA SEQ ID NO: 24 CACCTAACTCTCACAAACCAC SEQ ID NO: 25 ACCTAACTCATACAAACCACC SEQ ID NO: 26 ATATAGTTTCGTCATTCATC SEQ ID NO: 27 TACATTGCCCATGTAATTAA SEQ ID NO: 28 ATATAGTTTCGTCATTCATC SEQ ID NO: 29 TACATTGCCCATGTAATTAA SEQ ID NO: 30 AGATAGTTTTGTCATTCATC SEQ ID NO: 31 AGATAGTTTCTTCATTCATC SEQ ID NO: 32 AGATAGTTTCGTCATTCATC SEQ ID NO: 33 AGATAGTTTCGTTATTCATC SEQ ID NO: 34 CCTAACTCACTCAAACCACCA SEQ ID NO: 35 CTAACTCACATAAACCACCAA SEQ ID NO: 36 TAACTCACACTAACCACCAAC SEQ ID NO: 37 AACCAACCAAGAATCTCCCAC SEQ ID NO: 38 ACCAACCAATGATCTCCCACC SEQ ID NO: 39 CCAACCAATAGTCTCCCACCC SEQ ID NO: 40 CAACCAATAAGCTCCCACCCC SEQ ID NO: 41 AACCAATAATGTCCCACCCCA SEQ ID NO: 42 ACCAATAATCGCCCACCCCAC SEQ ID NO: 43 CCAATAATCTGCCACCCCACC SEQ ID NO: 44 CAATAATCTCGCACCCCACCT SEQ ID NO: 45 AATAATCTCCGACCCCACCTA SEQ ID NO: 46 ATAATCTCCCGCCCCACCTAA SEQ ID NO: 47 TAATCTCCCAGCCCACCTAAC SEQ ID NO: 48 AATCTCCCACGCCACCTAACT SEQ ID NO: 49 ATCTCCCACCGCACCTAACTC SEQ ID NO: 50 TCTCCCACCCGACCTAACTCA SEQ ID NO: 51 CTCCCACCCCGCCTAACTCAC SEQ ID NO: 52 TCCCACCCCAGCTAACTCACA SEQ ID NO: 53 CCCACCCCACGTAACTCACAC SEQ ID NO: 54 CCACCCCACCGAACTCACACA SEQ ID NO: 55 CACCCCACCTGACTCACACAA SEQ ID NO: 56 ACCCCACCTAGCTCACACAAA SEQ ID NO: 57 CCCCACCTAAGTCACACAAAC SEQ ID NO: 58 CCCACCTAACGCACACAAACC SEQ ID NO: 59 CCACCTAACTGACACAAACCA SEQ ID NO: 60 CACCTAACTCGCACAAACCAC SEQ ID NO: 61 ACCTAACTCAGACAAACCACC SEQ ID NO: 62 TACATTGCCCATGTAATTAA SEQ ID NO: 63 ATATAGTTTCGTCATTCATC SEQ ID NO: 64 TACATTGCCCATGTAATTAA SEQ ID NO: 65 ATATAGTTTCGTCATTCATC SEQ ID NO: 66 AGATAGTTTGGTCATTCATC SEQ ID NO: 67 AGATAGTTTCGTCATTCATC SEQ ID NO: 68 AGATAGTTTCGGCATTCATC SEQ ID NO: 69 AGATAGTTTCGTGATTCATC SEQ ID NO: 70 CCTAACTCACGCAAACCACCA SEQ ID NO: 71 CTAACTCACAGAAACCACCAA SEQ ID NO: 72 TAACTCACACGAACCACCAAC SEQ ID NO: 73 AACCAACCAACAATCTCCCAC SEQ ID NO: 74 ACCAACCAATCATCTCCCACC SEQ ID NO: 75 CCAACCAATACTCTCCCACCC SEQ ID NO: 76 CAACCAATAACCTCCCACCCC SEQ ID NO: 77 AACCAATAATCTCCCACCCCA SEQ ID NO: 78 ACCAATAATCCCCCACCCCAC SEQ ID NO: 79 CCAATAATCTCCCACCCCACC SEQ ID NO: 80 CAATAATCTCCCACCCCACCT SEQ ID NO: 81 AATAATCTCCCACCCCACCTA SEQ ID NO: 82 ATAATCTCCCCCCCCACCTAA SEQ ID NO: 83 TAATCTCCCACCCCACCTAAC SEQ ID NO: 84 AATCTCCCACCCCACCTAACT SEQ ID NO: 85 ATCTCCCACCCCACCTAACTC SEQ ID NO: 86 TCTCCCACCCCACCTAACTCA SEQ ID NO: 87 CTCCCACCCCCCCTAACTCAC SEQ ID NO: 88 TCCCACCCCACCTAACTCACA SEQ ID NO: 89 CCCACCCCACCTAACTCACAC SEQ ID NO: 90 CCACCCCACCCAACTCACACA SEQ ID NO: 91 CACCCCACCTCACTCACACAA SEQ ID NO: 92 ACCCCACCTACCTCACACAAA SEQ ID NO: 93 CCCCACCTAACTCACACAAAC SEQ ID NO: 94 CCCACCTAACCCACACAAACC SEQ ID NO: 95 CCACCTAACTCACACAAACCA SEQ ID NO: 96 CACCTAACTCCCACAAACCAC SEQ ID NO: 97 ACCTAACTCACACAAACCACC SEQ ID NO: 98 ATATAGTTTCGTCATTCATC SEQ ID NO: 99 TACATTGCCCATGTAATTAA SEQ ID NO: 100 ATATAGTTTCGTCATTCATC SEQ ID NO: 101 TACATTGCCCATGTAATTAA SEQ ID NO: 102 AGATAGTTTCGTCATTCATC SEQ ID NO: 103 AGATAGTTTCCTCATTCATC SEQ ID NO: 104 AGATAGTTTCGCCATTCATC SEQ ID NO: 105 AGATAGTTTCGTCATTCATC SEQ ID NO: 106 CCTAACTCACCCAAACCACCA SEQ ID NO: 107 CTAACTCACACAAACCACCAA SEQ ID NO: 108 TAACTCACACCAACCACCAAC SEQ ID NO: 109 AACCAACCAAAAATCTCCCAC SEQ ID NO: 110 ACCAACCAATAATCTCCCACC SEQ ID NO: 111 CCAACCAATAATCTCCCACCC SEQ ID NO: 112 CAACCAATAAACTCCCACCCC SEQ ID NO: 113 AACCAATAATATCCCACCCCA SEQ ID NO: 114 ACCAATAATCACCCACCCCAC SEQ ID NO: 115 CCAATAATCTACCACCCCACC SEQ ID NO: 116 CAATAATCTCACACCCCACCT SEQ ID NO: 117 AATAATCTCCAACCCCACCTA SEQ ID NO: 118 ATAATCTCCCACCCCACCTAA SEQ ID NO: 119 TAATCTCCCAACCCACCTAAC SEQ ID NO: 120 AATCTCCCACACCACCTAACT SEQ ID NO: 121 ATCTCCCACCACACCTAACTC SEQ ID NO: 122 TCTCCCACCCAACCTAACTCA SEQ ID NO: 123 CTCCCACCCCACCTAACTCAC SEQ ID NO: 124 TCCCACCCCAACTAACTCACA SEQ ID NO: 125 CCCACCCCACATAACTCACAC SEQ ID NO: 126 CCACCCCACCAAACTCACACA SEQ ID NO: 127 CACCCCACCTAACTCACACAA SEQ ID NO: 128 ACCCCACCTAACTCACACAAA SEQ ID NO: 129 CCCCACCTAAATCACACAAAC SEQ ID NO: 130 CCCACCTAACACACACAAACC SEQ ID NO: 131 CCACCTAACTAACACAAACCA SEQ ID NO: 132 CACCTAACTCACACAAACCAC SEQ ID NO: 133 ACCTAACTCAAACAAACCACC SEQ ID NO: 134 TACATTGCCCATGTAATTAA SEQ ID NO: 135 ATATAGTTTCGTCATTCATC SEQ ID NO: 136 TACATTGCCCATGTAATTAA SEQ ID NO: 137 ATATAGTTTCGTCATTCATC SEQ ID NO: 138 AGATAGTTTAGTCATTCATC SEQ ID NO: 139 AGATAGTTTCATCATTCATC SEQ ID NO: 140 AGATAGTTTCGACATTCATC SEQ ID NO: 141 AGATAGTTTCGTAATTCATC SEQ ID NO: 142 CCTAACTCACACAAACCACCA SEQ ID NO: 143 CTAACTCACAAAAACCACCAA SEQ ID NO: 144 TAACTCACACAAACCACCAAC SEQ ID NO: 145 AACTCACACATACCACCAACA SEQ ID NO: 146 ACTCACACAATCCACCAACAC SEQ ID NO: 147 CTCACACAAATCACCAACACC SEQ ID NO: 148 TCACACAAACTACCAACACCT SEQ ID NO: 149 CACACAAACCTCCAACACCTC SEQ ID NO: 150 ACACAAACCATCAACACCTCT SEQ ID NO: 151 CACAAACCACTAACACCTCTC SEQ ID NO: 152 ACAAACCACCTACACCTCTCC SEQ ID NO: 153 CAAACCACCATCACCTCTCCC SEQ ID NO: 154 AAACCACCAATACCTCTCCCC SEQ ID NO: 155 AACCACCAACTCCTCTCCCCC SEQ ID NO: 156 ACCACCAACATCTCTCCCCCT SEQ ID NO: 157 CCACCAACACTTCTCCCCCTC SEQ ID NO: 158 CACCAACACCTCTCCCCCTCT SEQ ID NO: 159 ACCAACACCTTTCCCCCTCTC SEQ ID NO: 160 CCAACACCTCTCCCCCTCTCA SEQ ID NO: 161 CAACACCTCTTCCCCTCTCAT SEQ ID NO: 162 AACACCTCTCTCCCTCTCATC SEQ ID NO: 163 ACACCTCTCCTCCTCTCATCC SEQ ID NO: 164 CACCTCTCCCTCTCTCATCCA SEQ ID NO: 165 ACCTCTCCCCTTCTCATCCAT SEQ ID NO: 166 CCTCTCCCCCTCTCATCCATC SEQ ID NO: 167 ATATAGTTTCGTCATTCATC SEQ ID NO: 168 TACATTGCCCATGTAATTAA SEQ ID NO: 169 ATATAGTTTCGTCATTCATC SEQ ID NO: 170 TACATTGCCCATGTAATTAA SEQ ID NO: 171 AGATAGTTTTGTCATTCATC SEQ ID NO: 172 AGATAGTTTCTTCATTCATC SEQ ID NO: 173 AGATAGTTTCGTCATTCATC SEQ ID NO: 174 AGATAGTTTCGTTATTCATC SEQ ID NO: 175 CTCTCCCCCTTTCATCCATCA SEQ ID NO: 176 TCTCCCCCTCTCATCCATCAC SEQ ID NO: 177 CTCCCCCTCTTATCCATCACC SEQ ID NO: 178 TCCCCCTCTCTTCCATCACCC SEQ ID NO: 179 CCCCCTCTCATCCATCACCCA SEQ ID NO: 180 CCCCTCTCATTCATCACCCAC SEQ ID NO: 181 AACTCACACAGACCACCAACA SEQ ID NO: 182 ACTCACACAAGCCACCAACAC SEQ ID NO: 183 CTCACACAAAGCACCAACACC SEQ ID NO: 184 TCACACAAACGACCAACACCT SEQ ID NO: 185 CACACAAACCGCCAACACCTC SEQ ID NO: 186 ACACAAACCAGCAACACCTCT SEQ ID NO: 187 CACAAACCACGAACACCTCTC SEQ ID NO: 188 ACAAACCACCGACACCTCTCC SEQ ID NO: 189 CAAACCACCAGCACCTCTCCC SEQ ID NO: 190 AAACCACCAAGACCTCTCCCC SEQ ID NO: 191 AACCACCAACGCCTCTCCCCC SEQ ID NO: 192 ACCACCAACAGCTCTCCCCCT SEQ ID NO: 193 CCACCAACACGTCTCCCCCTC SEQ ID NO: 194 CACCAACACCGCTCCCCCTCT SEQ ID NO: 195 ACCAACACCTGTCCCCCTCTC SEQ ID NO: 196 CCAACACCTCGCCCCCTCTCA SEQ ID NO: 197 CAACACCTCTGCCCCTCTCAT SEQ ID NO: 198 AACACCTCTCGCCCTCTCATC SEQ ID NO: 199 ACACCTCTCCGCCTCTCATCC SEQ ID NO: 200 CACCTCTCCCGCTCTCATCCA SEQ ID NO: 201 ACCTCTCCCCGTCTCATCCAT SEQ ID NO: 202 CCTCTCCCCCGCTCATCCATC SEQ ID NO: 203 TACATTGCCCATGTAATTAA SEQ ID NO: 204 ATATAGTTTCGTCATTCATC SEQ ID NO: 205 TACATTGCCCATGTAATTAA SEQ ID NO: 206 ATATAGTTTCGTCATTCATC SEQ ID NO: 207 AGATAGTTTGGTCATTCATC SEQ ID NO: 208 AGATAGTTTCGTCATTCATC SEQ ID NO: 209 AGATAGTTTCGGCATTCATC SEQ ID NO: 210 AGATAGTTTCGTGATTCATC SEQ ID NO: 211 CTCTCCCCCTGTCATCCATCA SEQ ID NO: 212 TCTCCCCCTCGCATCCATCAC SEQ ID NO: 213 CTCCCCCTCTGATCCATCACC SEQ ID NO: 214 TCCCCCTCTCGTCCATCACCC SEQ ID NO: 215 CCCCCTCTCAGCCATCACCCA SEQ ID NO: 216 CCCCTCTCATGCATCACCCAC SEQ ID NO: 217 AACTCACACACACCACCAACA SEQ ID NO: 218 ACTCACACAACCCACCAACAC SEQ ID NO: 219 CTCACACAAACCACCAACACC SEQ ID NO: 220 TCACACAAACCACCAACACCT SEQ ID NO: 221 CACACAAACCCCCAACACCTC SEQ ID NO: 222 ACACAAACCACCAACACCTCT SEQ ID NO: 223 CACAAACCACCAACACCTCTC SEQ ID NO: 224 ACAAACCACCCACACCTCTCC SEQ ID NO: 225 CAAACCACCACCACCTCTCCC SEQ ID NO: 226 AAACCACCAACACCTCTCCCC SEQ ID NO: 227 AACCACCAACCCCTCTCCCCC SEQ ID NO: 228 ACCACCAACACCTCTCCCCCT SEQ ID NO: 229 CCACCAACACCTCTCCCCCTC SEQ ID NO: 230 CACCAACACCCCTCCCCCTCT SEQ ID NO: 231 ACCAACACCTCTCCCCCTCTC SEQ ID NO: 232 CCAACACCTCCCCCCCTCTCA SEQ ID NO: 233 CAACACCTCTCCCCCTCTCAT SEQ ID NO: 234 AACACCTCTCCCCCTCTCATC SEQ ID NO: 235 ACACCTCTCCCCCTCTCATCC SEQ ID NO: 236 CACCTCTCCCCCTCTCATCCA SEQ ID NO: 237 ACCTCTCCCCCTCTCATCCAT SEQ ID NO: 238 CCTCTCCCCCCCTCATCCATC SEQ ID NO: 239 ATATAGTTTCGTCATTCATC SEQ ID NO: 240 TACATTGCCCATGTAATTAA SEQ ID NO: 241 ATATAGTTTCGTCATTCATC SEQ ID NO: 242 TACATTGCCCATGTAATTAA SEQ ID NO: 243 AGATAGTTTCGTCATTCATC SEQ ID NO: 244 AGATAGTTTCCTCATTCATC SEQ ID NO: 245 AGATAGTTTCGCCATTCATC SEQ ID NO: 246 AGATAGTTTCGTCATTCATC SEQ ID NO: 247 CTCTCCCCCTCTCATCCATCA SEQ ID NO: 248 TCTCCCCCTCCCATCCATCAC SEQ ID NO: 249 CTCCCCCTCTCATCCATCACC SEQ ID NO: 250 TCCCCCTCTCCTCCATCACCC SEQ ID NO: 251 CCCCCTCTCACCCATCACCCA SEQ ID NO: 252 CCCCTCTCATCCATCACCCAC SEQ ID NO: 253 AACTCACACAAACCACCAACA SEQ ID NO: 254 ACTCACACAAACCACCAACAC SEQ ID NO: 255 CTCACACAAAACACCAACACC SEQ ID NO: 256 TCACACAAACAACCAACACCT SEQ ID NO: 257 CACACAAACCACCAACACCTC SEQ ID NO: 258 ACACAAACCAACAACACCTCT SEQ ID NO: 259 CACAAACCACAAACACCTCTC SEQ ID NO: 260 ACAAACCACCAACACCTCTCC SEQ ID NO: 261 CAAACCACCAACACCTCTCCC SEQ ID NO: 262 AAACCACCAAAACCTCTCCCC SEQ ID NO: 263 AACCACCAACACCTCTCCCCC SEQ ID NO: 264 ACCACCAACAACTCTCCCCCT SEQ ID NO: 265 CCACCAACACATCTCCCCCTC SEQ ID NO: 266 CACCAACACCACTCCCCCTCT SEQ ID NO: 267 ACCAACACCTATCCCCCTCTC SEQ ID NO: 268 CCAACACCTCACCCCCTCTCA SEQ ID NO: 269 CAACACCTCTACCCCTCTCAT SEQ ID NO: 270 AACACCTCTCACCCTCTCATC SEQ ID NO: 271 ACACCTCTCCACCTCTCATCC SEQ ID NO: 272 CACCTCTCCCACTCTCATCCA SEQ ID NO: 273 ACCTCTCCCCATCTCATCCAT SEQ ID NO: 274 CCTCTCCCCCACTCATCCATC SEQ ID NO: 275 TACATTGCCCATGTAATTAA SEQ ID NO: 276 ATATAGTTTCGTCATTCATC SEQ ID NO: 277 TACATTGCCCATGTAATTAA SEQ ID NO: 278 ATATAGTTTCGTCATTCATC SEQ ID NO: 279 AGATAGTTTAGTCATTCATC SEQ ID NO: 280 AGATAGTTTCATCATTCATC SEQ ID NO: 281 AGATAGTTTCGACATTCATC SEQ ID NO: 282 AGATAGTTTCGTAATTCATC SEQ ID NO: 283 CTCTCCCCCTATCATCCATCA SEQ ID NO: 284 TCTCCCCCTCACATCCATCAC SEQ ID NO: 285 CTCCCCCTCTAATCCATCACC SEQ ID NO: 286 TCCCCCTCTCATCCATCACCC SEQ ID NO: 287 CCCCCTCTCAACCATCACCCA SEQ ID NO: 288 CCCCTCTCATACATCACCCAC SEQ ID NO: 289 CCCTCTCATCTATCACCCACC SEQ ID NO: 290 CCTCTCATCCTTCACCCACCA SEQ ID NO: 291 CTCTCATCCATCACCCACCAC SEQ ID NO: 292 TCTCATCCATTACCCACCACC SEQ ID NO: 293 CTCATCCATCTCCCACCACCC SEQ ID NO: 294 TCATCCATCATCCACCACCCC SEQ ID NO: 295 CATCCATCACTCACCACCCCT SEQ ID NO: 296 ATCCATCACCTACCACCCCTC SEQ ID NO: 297 TCCATCACCCTCCACCCCTCA SEQ ID NO: 298 CCATCACCCATCACCCCTCAT SEQ ID NO: 299 CATCACCCACTACCCCTCATC SEQ ID NO: 300 ATCACCCACCTCCCCTCATCA SEQ ID NO: 301 TCACCCACCATCCCTCATCAT SEQ ID NO: 302 CACCCACCACTCCTCATCATA SEQ ID NO: 303 ACCCACCACCTCTCATCATAC SEQ ID NO: 304 CCCACCACCCTTCATCATACC SEQ ID NO: 305 CCACCACCCCTCATCATACCT SEQ ID NO: 306 CACCACCCCTTATCATACCTC SEQ ID NO: 307 ACCACCCCTCTTCATACCTCA SEQ ID NO: 308 ATATAGTTTCGTCATTCATC SEQ ID NO: 309 TACATTGCCCATGTAATTAA SEQ ID NO: 310 ATATAGTTTCGTCATTCATC SEQ ID NO: 311 TACATTGCCCATGTAATTAA SEQ ID NO: 312 AGATAGTTTTGTCATTCATC SEQ ID NO: 313 AGATAGTTTCTTCATTCATC SEQ ID NO: 314 AGATAGTTTCGTCATTCATC SEQ ID NO: 315 AGATAGTTTCGTTATTCATC SEQ ID NO: 316 CCACCCCTCATCATACCTCAA SEQ ID NO: 317 CACCCCTCATTATACCTCAAC SEQ ID NO: 318 ACCCCTCATCTTACCTCAACC SEQ ID NO: 319 CCCCTCATCATACCTCAACCA SEQ ID NO: 320 CCCTCATCATTCCTCAACCAC SEQ ID NO: 321 CCTCATCATATCTCAACCACC SEQ ID NO: 322 CTCATCATACTTCAACCACCA SEQ ID NO: 323 TCATCATACCTCAACCACCAC SEQ ID NO: 324 CATCATACCTTAACCACCACC SEQ ID NO: 325 CCCTCTCATCGATCACCCACC SEQ ID NO: 326 CCTCTCATCCGTCACCCACCA SEQ ID NO: 327 CTCTCATCCAGCACCCACCAC SEQ ID NO: 328 TCTCATCCATGACCCACCACC SEQ ID NO: 329 CTCATCCATCGCCCACCACCC SEQ ID NO: 330 TCATCCATCAGCCACCACCCC SEQ ID NO: 331 CATCCATCACGCACCACCCCT SEQ ID NO: 332 ATCCATCACCGACCACCCCTC SEQ ID NO: 333 TCCATCACCCGCCACCCCTCA SEQ ID NO: 334 CCATCACCCAGCACCCCTCAT SEQ ID NO: 335 CATCACCCACGACCCCTCATC SEQ ID NO: 336 ATCACCCACCGCCCCTCATCA SEQ ID NO: 337 TCACCCACCAGCCCTCATCAT SEQ ID NO: 338 CACCCACCACGCCTCATCATA SEQ ID NO: 339 ACCCACCACCGCTCATCATAC SEQ ID NO: 340 CCCACCACCCGTCATCATACC SEQ ID NO: 341 CCACCACCCCGCATCATACCT SEQ ID NO: 342 CACCACCCCTGATCATACCTC SEQ ID NO: 343 ACCACCCCTCGTCATACCTCA SEQ ID NO: 344 TACATTGCCCATGTAATTAA SEQ ID NO: 345 ATATAGTTTCGTCATTCATC SEQ ID NO: 346 TACATTGCCCATGTAATTAA SEQ ID NO: 347 ATATAGTTTCGTCATTCATC SEQ ID NO: 348 AGATAGTTTGGTCATTCATC SEQ ID NO: 349 AGATAGTTTCGTCATTCATC SEQ ID NO: 350 AGATAGTTTCGGCATTCATC SEQ ID NO: 351 AGATAGTTTCGTGATTCATC SEQ ID NO: 352 CCACCCCTCAGCATACCTCAA SEQ ID NO: 353 CACCCCTCATGATACCTCAAC SEQ ID NO: 354 ACCCCTCATCGTACCTCAACC SEQ ID NO: 355 CCCCTCATCAGACCTCAACCA SEQ ID NO: 356 CCCTCATCATGCCTCAACCAC SEQ ID NO: 357 CCTCATCATAGCTCAACCACC SEQ ID NO: 358 CTCATCATACGTCAACCACCA SEQ ID NO: 359 TCATCATACCGCAACCACCAC SEQ ID NO: 360 CATCATACCTGAACCACCACC SEQ ID NO: 361 CCCTCTCATCCATCACCCACC SEQ ID NO: 362 CCTCTCATCCCTCACCCACCA SEQ ID NO: 363 CTCTCATCCACCACCCACCAC SEQ ID NO: 364 TCTCATCCATCACCCACCACC SEQ ID NO: 365 CTCATCCATCCCCCACCACCC SEQ ID NO: 366 TCATCCATCACCCACCACCCC SEQ ID NO: 367 CATCCATCACCCACCACCCCT SEQ ID NO: 368 ATCCATCACCCACCACCCCTC SEQ ID NO: 369 TCCATCACCCCCCACCCCTCA SEQ ID NO: 370 CCATCACCCACCACCCCTCAT SEQ ID NO: 371 CATCACCCACCACCCCTCATC SEQ ID NO: 372 ATCACCCACCCCCCCTCATCA SEQ ID NO: 373 TCACCCACCACCCCTCATCAT SEQ ID NO: 374 CACCCACCACCCCTCATCATA SEQ ID NO: 375 ACCCACCACCCCTCATCATAC SEQ ID NO: 376 CCCACCACCCCTCATCATACC SEQ ID NO: 377 CCACCACCCCCCATCATACCT SEQ ID NO: 378 CACCACCCCTCATCATACCTC SEQ ID NO: 379 ACCACCCCTCCTCATACCTCA SEQ ID NO: 380 ATATAGTTTCGTCATTCATC SEQ ID NO: 381 TACATTGCCCATGTAATTAA SEQ ID NO: 382 ATATAGTTTCGTCATTCATC SEQ ID NO: 383 TACATTGCCCATGTAATTAA SEQ ID NO: 384 AGATAGTTTCGTCATTCATC SEQ ID NO: 385 AGATAGTTTCCTCATTCATC SEQ ID NO: 386 AGATAGTTTCGCCATTCATC SEQ ID NO: 387 AGATAGTTTCGTCATTCATC SEQ ID NO: 388 CCACCCCTCACCATACCTCAA SEQ ID NO: 389 CACCCCTCATCATACCTCAAC SEQ ID NO: 390 ACCCCTCATCCTACCTCAACC SEQ ID NO: 391 CCCCTCATCACACCTCAACCA SEQ ID NO: 392 CCCTCATCATCCCTCAACCAC SEQ ID NO: 393 CCTCATCATACCTCAACCACC SEQ ID NO: 394 CTCATCATACCTCAACCACCA SEQ ID NO: 395 TCATCATACCCCAACCACCAC SEQ ID NO: 396 CATCATACCTCAACCACCACC SEQ ID NO: 397 CCCTCTCATCAATCACCCACC SEQ ID NO: 398 CCTCTCATCCATCACCCACCA SEQ ID NO: 399 CTCTCATCCAACACCCACCAC SEQ ID NO: 400 TCTCATCCATAACCCACCACC SEQ ID NO: 401 CTCATCCATCACCCACCACCC SEQ ID NO: 402 TCATCCATCAACCACCACCCC SEQ ID NO: 403 CATCCATCACACACCACCCCT SEQ ID NO: 404 ATCCATCACCAACCACCCCTC SEQ ID NO: 405 TCCATCACCCACCACCCCTCA SEQ ID NO: 406 CCATCACCCAACACCCCTCAT SEQ ID NO: 407 CATCACCCACAACCCCTCATC SEQ ID NO: 408 ATCACCCACCACCCCTCATCA SEQ ID NO: 409 TCACCCACCAACCCTCATCAT SEQ ID NO: 410 CACCCACCACACCTCATCATA SEQ ID NO: 411 ACCCACCACCACTCATCATAC SEQ ID NO: 412 CCCACCACCCATCATCATACC SEQ ID NO: 413 CCACCACCCCACATCATACCT SEQ ID NO: 414 CACCACCCCTAATCATACCTC SEQ ID NO: 415 ACCACCCCTCATCATACCTCA SEQ ID NO: 416 TACATTGCCCATGTAATTAA SEQ ID NO: 417 ATATAGTTTCGTCATTCATC SEQ ID NO: 418 TACATTGCCCATGTAATTAA SEQ ID NO: 419 ATATAGTTTCGTCATTCATC SEQ ID NO: 420 AGATAGTTTAGTCATTCATC SEQ ID NO: 421 AGATAGTTTCATCATTCATC SEQ ID NO: 422 AGATAGTTTCGACATTCATC SEQ ID NO: 423 AGATAGTTTCGTAATTCATC SEQ ID NO: 424 CCACCCCTCAACATACCTCAA SEQ ID NO: 425 CACCCCTCATAATACCTCAAC SEQ ID NO: 426 ACCCCTCATCATACCTCAACC SEQ ID NO: 427 CCCCTCATCAAACCTCAACCA SEQ ID NO: 428 CCCTCATCATACCTCAACCAC SEQ ID NO: 429 CCTCATCATAACTCAACCACC SEQ ID NO: 430 CTCATCATACATCAACCACCA SEQ ID NO: 431 TCATCATACCACAACCACCAC SEQ ID NO: 432 CATCATACCTAAACCACCACC SEQ ID NO: 433 ATCATACCTCTACCACCACCC SEQ ID NO: 434 TCATACCTCATCCACCACCCC SEQ ID NO: 435 CATACCTCAATCACCACCCCT SEQ ID NO: 436 ATACCTCAACTACCACCCCTC SEQ ID NO: 437 TACCTCAACCTCCACCCCTCA SEQ ID NO: 438 ACCTCAACCATCACCCCTCAT SEQ ID NO: 439 CCTCAACCACTACCCCTCATC SEQ ID NO: 440 CTCAACCACCTCCCCTCATCA SEQ ID NO: 441 TCAACCACCATCCCTCATCAT SEQ ID NO: 442 CAACCACCACTCCTCATCATA SEQ ID NO: 443 AACCACCACCTCTCATCATAC SEQ ID NO: 444 ACCACCACCCTTCATCATACC SEQ ID NO: 445 CCACCACCCCTCATCATACCT SEQ ID NO: 446 CACCACCCCTTATCATACCTC SEQ ID NO: 447 ACCACCCCTCTTCATACCTCA SEQ ID NO: 448 CCACCCCTCATCATACCTCAA SEQ ID NO: 449 ATATAGTTTCGTCATTCATC SEQ ID NO: 450 TACATTGCCCATGTAATTAA SEQ ID NO: 451 ATATAGTTTCGTCATTCATC SEQ ID NO: 452 TACATTGCCCATGTAATTAA SEQ ID NO: 453 AGATAGTTTTGTCATTCATC SEQ ID NO: 454 AGATAGTTTCTTCATTCATC SEQ ID NO: 455 AGATAGTTTCGTCATTCATC SEQ ID NO: 456 AGATAGTTTCGTTATTCATC SEQ ID NO: 457 CACCCCTCATTATACCTCAAA SEQ ID NO: 458 ACCCCTCATCTTACCTCAAAA SEQ ID NO: 459 CCCCTCATCATACCTCAAAAA SEQ ID NO: 460 CCCTCATCATTCCTCAAAAAC SEQ ID NO: 461 CCTCATCATATCTCAAAAACC SEQ ID NO: 462 CTCATCATACTTCAAAAACCA SEQ ID NO: 463 TCATCATACCTCAAAAACCAA SEQ ID NO: 464 CATCATACCTTAAAAACCAAC SEQ ID NO: 465 ATCATACCTCTAAAACCAACT SEQ ID NO: 466 TCATACCTCATAAACCAACTA SEQ ID NO: 467 CATACCTCAATAACCAACTAA SEQ ID NO: 468 ATACCTCAAATACCAACTAAC SEQ ID NO: 469 ATCATACCTCGACCACCACCC SEQ ID NO: 470 TCATACCTCAGCCACCACCCC SEQ ID NO: 471 CATACCTCAAGCACCACCCCT SEQ ID NO: 472 ATACCTCAACGACCACCCCTC SEQ ID NO: 473 TACCTCAACCGCCACCCCTCA SEQ ID NO: 474 ACCTCAACCAGCACCCCTCAT SEQ ID NO: 475 CCTCAACCACGACCCCTCATC SEQ ID NO: 476 CTCAACCACCGCCCCTCATCA SEQ ID NO: 477 TCAACCACCAGCCCTCATCAT SEQ ID NO: 478 CAACCACCACGCCTCATCATA SEQ ID NO: 479 AACCACCACCGCTCATCATAC SEQ ID NO: 480 ACCACCACCCGTCATCATACC SEQ ID NO: 481 CCACCACCCCGCATCATACCT SEQ ID NO: 482 CACCACCCCTGATCATACCTC SEQ ID NO: 483 ACCACCCCTCGTCATACCTCA SEQ ID NO: 484 CCACCCCTCAGCATACCTCAA SEQ ID NO: 485 TACATTGCCCATGTAATTAA SEQ ID NO: 486 ATATAGTTTCGTCATTCATC SEQ ID NO: 487 TACATTGCCCATGTAATTAA SEQ ID NO: 488 ATATAGTTTCGTCATTCATC SEQ ID NO: 489 AGATAGTTTGGTCATTCATC SEQ ID NO: 490 AGATAGTTTCGTCATTCATC SEQ ID NO: 491 AGATAGTTTCGGCATTCATC SEQ ID NO: 492 AGATAGTTTCGTGATTCATC SEQ ID NO: 493 CACCCCTCATGATACCTCAAA SEQ ID NO: 494 ACCCCTCATCGTACCTCAAAA SEQ ID NO: 495 CCCCTCATCAGACCTCAAAAA SEQ ID NO: 496 CCCTCATCATGCCTCAAAAAC SEQ ID NO: 497 CCTCATCATAGCTCAAAAACC SEQ ID NO: 498 CTCATCATACGTCAAAAACCA SEQ ID NO: 499 TCATCATACCGCAAAAACCAA SEQ ID NO: 500 CATCATACCTGAAAAACCAAC SEQ ID NO: 501 ATCATACCTCGAAAACCAACT SEQ ID NO: 502 TCATACCTCAGAAACCAACTA SEQ ID NO: 503 CATACCTCAAGAACCAACTAA SEQ ID NO: 504 ATACCTCAAAGACCAACTAAC SEQ ID NO: 505 ATCATACCTCCACCACCACCC SEQ ID NO: 506 TCATACCTCACCCACCACCCC SEQ ID NO: 507 CATACCTCAACCACCACCCCT SEQ ID NO: 508 ATACCTCAACCACCACCCCTC SEQ ID NO: 509 TACCTCAACCCCCACCCCTCA SEQ ID NO: 510 ACCTCAACCACCACCCCTCAT SEQ ID NO: 511 CCTCAACCACCACCCCTCATC SEQ ID NO: 512 CTCAACCACCCCCCCTCATCA SEQ ID NO: 513 TCAACCACCACCCCTCATCAT SEQ ID NO: 514 CAACCACCACCCCTCATCATA SEQ ID NO: 515 AACCACCACCCCTCATCATAC SEQ ID NO: 516 ACCACCACCCCTCATCATACC SEQ ID NO: 517 CCACCACCCCCCATCATACCT SEQ ID NO: 518 CACCACCCCTCATCATACCTC SEQ ID NO: 519 ACCACCCCTCCTCATACCTCA SEQ ID NO: 520 CCACCCCTCACCATACCTCAA SEQ ID NO: 521 ATATAGTTTCGTCATTCATC SEQ ID NO: 522 TACATTGCCCATGTAATTAA SEQ ID NO: 523 ATATAGTTTCGTCATTCATC SEQ ID NO: 524 TACATTGCCCATGTAATTAA SEQ ID NO: 525 AGATAGTTTCGTCATTCATC SEQ ID NO: 526 AGATAGTTTCCTCATTCATC SEQ ID NO: 527 AGATAGTTTCGCCATTCATC SEQ ID NO: 528 AGATAGTTTCGTCATTCATC SEQ ID NO: 529 CACCCCTCATCATACCTCAAA SEQ ID NO: 530 ACCCCTCATCCTACCTCAAAA SEQ ID NO: 531 CCCCTCATCACACCTCAAAAA SEQ ID NO: 532 CCCTCATCATCCCTCAAAAAC SEQ ID NO: 533 CCTCATCATACCTCAAAAACC SEQ ID NO: 534 CTCATCATACCTCAAAAACCA SEQ ID NO: 535 TCATCATACCCCAAAAACCAA SEQ ID NO: 536 CATCATACCTCAAAAACCAAC SEQ ID NO: 537 ATCATACCTCCAAAACCAACT SEQ ID NO: 538 TCATACCTCACAAACCAACTA SEQ ID NO: 539 CATACCTCAACAACCAACTAA SEQ ID NO: 540 ATACCTCAAACACCAACTAAC SEQ ID NO: 541 ATCATACCTCAACCACCACCC SEQ ID NO: 542 TCATACCTCAACCACCACCCC SEQ ID NO: 543 CATACCTCAAACACCACCCCT SEQ ID NO: 544 ATACCTCAACAACCACCCCTC SEQ ID NO: 545 TACCTCAACCACCACCCCTCA SEQ ID NO: 546 ACCTCAACCAACACCCCTCAT SEQ ID NO: 547 CCTCAACCACAACCCCTCATC SEQ ID NO: 548 CTCAACCACCACCCCTCATCA SEQ ID NO: 549 TCAACCACCAACCCTCATCAT SEQ ID NO: 550 CAACCACCACACCTCATCATA SEQ ID NO: 551 AACCACCACCACTCATCATAC SEQ ID NO: 552 ACCACCACCCATCATCATACC SEQ ID NO: 553 CCACCACCCCACATCATACCT SEQ ID NO: 554 CACCACCCCTAATCATACCTC SEQ ID NO: 555 ACCACCCCTCATCATACCTCA SEQ ID NO: 556 CCACCCCTCAACATACCTCAA SEQ ID NO: 557 TACATTGCCCATGTAATTAA SEQ ID NO: 558 ATATAGTTTCGTCATTCATC SEQ ID NO: 559 TACATTGCCCATGTAATTAA SEQ ID NO: 560 ATATAGTTTCGTCATTCATC SEQ ID NO: 561 AGATAGTTTAGTCATTCATC SEQ ID NO: 562 AGATAGTTTCATCATTCATC SEQ ID NO: 563 AGATAGTTTCGACATTCATC SEQ ID NO: 564 AGATAGTTTCGTAATTCATC SEQ ID NO: 565 CACCCCTCATAATACCTCAAA SEQ ID NO: 566 ACCCCTCATCATACCTCAAAA SEQ ID NO: 567 CCCCTCATCAAACCTCAAAAA SEQ ID NO: 568 CCCTCATCATACCTCAAAAAC SEQ ID NO: 569 CCTCATCATAACTCAAAAACC SEQ ID NO: 570 CTCATCATACATCAAAAACCA SEQ ID NO: 571 TCATCATACCACAAAAACCAA SEQ ID NO: 572 CATCATACCTAAAAAACCAAC SEQ ID NO: 573 ATCATACCTCAAAAACCAACT SEQ ID NO: 574 TCATACCTCAAAAACCAACTA SEQ ID NO: 575 CATACCTCAAAAACCAACTAA SEQ ID NO: 576 ATACCTCAAAAACCAACTAAC SEQ ID NO: 577 TACCTCAAAATCCAACTAACC SEQ ID NO: 578 ACCTCAAAAATCAACTAACCA SEQ ID NO: 579 CCTCAAAAACTAACTAACCAA SEQ ID NO: 580 CTCAAAAACCTACTAACCAAC SEQ ID NO: 581 TCAAAAACCATCTAACCAACC SEQ ID NO: 582 CAAAAACCAATTAACCAACCA SEQ ID NO: 583 AAAAACCAACTAACCAACCAA SEQ ID NO: 584 AAAACCAACTTACCAACCAAT SEQ ID NO: 585 AACCAACCAATAATCTCCCAC SEQ ID NO: 586 ACCAACCAATTATCTCCCACC SEQ ID NO: 587 CCAACCAATATTCTCCCACCC SEQ ID NO: 588 CAACCAATAATCTCCCACCCC SEQ ID NO: 589 AACCAATAATTTCCCACCCCG SEQ ID NO: 590 ATATAGTTTCGTCATTCATC SEQ ID NO: 591 TACATTGCCCATGTAATTAA SEQ ID NO: 592 ATATAGTTTCGTCATTCATC SEQ ID NO: 593 TACATTGCCCATGTAATTAA SEQ ID NO: 594 AGATAGTTTTGTCATTCATC SEQ ID NO: 595 AGATAGTTTCTTCATTCATC SEQ ID NO: 596 AGATAGTTTCGTCATTCATC SEQ ID NO: 597 AGATAGTTTCGTTATTCATC SEQ ID NO: 598 ACCAATAATCTCCCACCCCGC SEQ ID NO: 599 CCAATAATCTTCCACCCCGCC SEQ ID NO: 600 CAATAATCTCTCACCCCGCCT SEQ ID NO: 601 AATAATCTCCTACCCCGCCTA SEQ ID NO: 602 ATAATCTCCCTCCCCGCCTAG SEQ ID NO: 603 TAATCTCCCATCCCGCCTAGC SEQ ID NO: 604 AATCTCCCACTCCGCCTAGCT SEQ ID NO: 605 ATCTCCCACCTCGCCTAGCTC SEQ ID NO: 606 TCTCCCACCCTGCCTAGCTCA SEQ ID NO: 607 CTCCCACCCCTCCTAGCTCAC SEQ ID NO: 608 TCCCACCCCGTCTAGCTCACG SEQ ID NO: 609 CCCACCCCGCTTAGCTCACGC SEQ ID NO: 610 CCACCCCGCCTAGCTCACGCA SEQ ID NO: 611 CACCCCGCCTTGCTCACGCAA SEQ ID NO: 612 ACCCCGCCTATCTCACGCAAG SEQ ID NO: 613 TACCTCAAAAGCCAACTAACC SEQ ID NO: 614 ACCTCAAAAAGCAACTAACCA SEQ ID NO: 615 CCTCAAAAACGAACTAACCAA SEQ ID NO: 616 CTCAAAAACCGACTAACCAAC SEQ ID NO: 617 TCAAAAACCAGCTAACCAACC SEQ ID NO: 618 CAAAAACCAAGTAACCAACCA SEQ ID NO: 619 AAAAACCAACGAACCAACCAA SEQ ID NO: 620 AAAACCAACTGACCAACCAAT SEQ ID NO: 621 AACCAACCAAGAATCTCCCAC SEQ ID NO: 622 ACCAACCAATGATCTCCCACC SEQ ID NO: 623 CCAACCAATAGTCTCCCACCC SEQ ID NO: 624 CAACCAATAAGCTCCCACCCC SEQ ID NO: 625 AACCAATAATGTCCCACCCCG SEQ ID NO: 626 TACATTGCCCATGTAATTAA SEQ ID NO: 627 ATATAGTTTCGTCATTCATC SEQ ID NO: 628 TACATTGCCCATGTAATTAA SEQ ID NO: 629 ATATAGTTTCGTCATTCATC SEQ ID NO: 630 AGATAGTTTGGTCATTCATC SEQ ID NO: 631 AGATAGTTTCGTCATTCATC SEQ ID NO: 632 AGATAGTTTCGGCATTCATC SEQ ID NO: 633 AGATAGTTTCGTGATTCATC SEQ ID NO: 634 ACCAATAATCGCCCACCCCGC SEQ ID NO: 635 CCAATAATCTGCCACCCCGCC SEQ ID NO: 636 CAATAATCTCGCACCCCGCCT SEQ ID NO: 637 AATAATCTCCGACCCCGCCTA SEQ ID NO: 638 ATAATCTCCCGCCCCGCCTAG SEQ ID NO: 639 TAATCTCCCAGCCCGCCTAGC SEQ ID NO: 640 AATCTCCCACGCCGCCTAGCT SEQ ID NO: 641 ATCTCCCACCGCGCCTAGCTC SEQ ID NO: 642 TCTCCCACCCGGCCTAGCTCA SEQ ID NO: 643 CTCCCACCCCGCCTAGCTCAC SEQ ID NO: 644 TCCCACCCCGGCTAGCTCACG SEQ ID NO: 645 CCCACCCCGCGTAGCTCACGC SEQ ID NO: 646 CCACCCCGCCGAGCTCACGCA SEQ ID NO: 647 CACCCCGCCTGGCTCACGCAA SEQ ID NO: 648 ACCCCGCCTAGCTCACGCAAG SEQ ID NO: 649 TACCTCAAAACCCAACTAACC SEQ ID NO: 650 ACCTCAAAAACCAACTAACCA SEQ ID NO: 651 CCTCAAAAACCAACTAACCAA SEQ ID NO: 652 CTCAAAAACCCACTAACCAAC SEQ ID NO: 653 TCAAAAACCACCTAACCAACC SEQ ID NO: 654 CAAAAACCAACTAACCAACCA SEQ ID NO: 655 AAAAACCAACCAACCAACCAA SEQ ID NO: 656 AAAACCAACTCACCAACCAAT SEQ ID NO: 657 AACCAACCAACAATCTCCCAC SEQ ID NO: 658 ACCAACCAATCATCTCCCACC SEQ ID NO: 659 CCAACCAATACTCTCCCACCC SEQ ID NO: 660 CAACCAATAACCTCCCACCCC SEQ ID NO: 661 AACCAATAATCTCCCACCCCG SEQ ID NO: 662 ATATAGTTTCGTCATTCATC SEQ ID NO: 663 TACATTGCCCATGTAATTAA SEQ ID NO: 664 ATATAGTTTCGTCATTCATC SEQ ID NO: 665 TACATTGCCCATGTAATTAA SEQ ID NO: 666 AGATAGTTTCGTCATTCATC SEQ ID NO: 667 AGATAGTTTCCTCATTCATC SEQ ID NO: 668 AGATAGTTTCGCCATTCATC SEQ ID NO: 669 AGATAGTTTCGTCATTCATC SEQ ID NO: 670 ACCAATAATCCCCCACCCCGC SEQ ID NO: 671 CCAATAATCTCCCACCCCGCC SEQ ID NO: 672 CAATAATCTCCCACCCCGCCT SEQ ID NO: 673 AATAATCTCCCACCCCGCCTA SEQ ID NO: 674 ATAATCTCCCCCCCCGCCTAG SEQ ID NO: 675 TAATCTCCCACCCCGCCTAGC SEQ ID NO: 676 AATCTCCCACCCCGCCTAGCT SEQ ID NO: 677 ATCTCCCACCCCGCCTAGCTC SEQ ID NO: 678 TCTCCCACCCCGCCTAGCTCA SEQ ID NO: 679 CTCCCACCCCCCCTAGCTCAC SEQ ID NO: 680 TCCCACCCCGCCTAGCTCACG SEQ ID NO: 681 CCCACCCCGCCTAGCTCACGC SEQ ID NO: 682 CCACCCCGCCCAGCTCACGCA SEQ ID NO: 683 CACCCCGCCTCGCTCACGCAA SEQ ID NO: 684 ACCCCGCCTACCTCACGCAAG SEQ ID NO: 685 TACCTCAAAAACCAACTAACC SEQ ID NO: 686 ACCTCAAAAAACAACTAACCA SEQ ID NO: 687 CCTCAAAAACAAACTAACCAA SEQ ID NO: 688 CTCAAAAACCAACTAACCAAC SEQ ID NO: 689 TCAAAAACCAACTAACCAACC SEQ ID NO: 690 CAAAAACCAAATAACCAACCA SEQ ID NO: 691 AAAAACCAACAAACCAACCAA SEQ ID NO: 692 AAAACCAACTAACCAACCAAT SEQ ID NO: 693 AACCAACCAAAAATCTCCCAC SEQ ID NO: 694 ACCAACCAATAATCTCCCACC SEQ ID NO: 695 CCAACCAATAATCTCCCACCC SEQ ID NO: 696 CAACCAATAAACTCCCACCCC SEQ ID NO: 697 AACCAATAATATCCCACCCCG SEQ ID NO: 698 TACATTGCCCATGTAATTAA SEQ ID NO: 699 ATATAGTTTCGTCATTCATC SEQ ID NO: 700 TACATTGCCCATGTAATTAA SEQ ID NO: 701 ATATAGTTTCGTCATTCATC SEQ ID NO: 702 AGATAGTTTAGTCATTCATC SEQ ID NO: 703 AGATAGTTTCATCATTCATC SEQ ID NO: 704 AGATAGTTTCGACATTCATC SEQ ID NO: 705 AGATAGTTTCGTAATTCATC SEQ ID NO: 706 ACCAATAATCACCCACCCCGC SEQ ID NO: 707 CCAATAATCTACCACCCCGCC SEQ ID NO: 708 CAATAATCTCACACCCCGCCT SEQ ID NO: 709 AATAATCTCCAACCCCGCCTA SEQ ID NO: 710 ATAATCTCCCACCCCGCCTAG SEQ ID NO: 711 TAATCTCCCAACCCGCCTAGC SEQ ID NO: 712 AATCTCCCACACCGCCTAGCT SEQ ID NO: 713 ATCTCCCACCACGCCTAGCTC SEQ ID NO: 714 TCTCCCACCCAGCCTAGCTCA SEQ ID NO: 715 CTCCCACCCCACCTAGCTCAC SEQ ID NO: 716 TCCCACCCCGACTAGCTCACG SEQ ID NO: 717 CCCACCCCGCATAGCTCACGC SEQ ID NO: 718 CCACCCCGCCAAGCTCACGCA SEQ ID NO: 719 CACCCCGCCTAGCTCACGCAA SEQ ID NO: 720 ACCCCGCCTAACTCACGCAAG SEQ ID NO: 721 CCCCGCCTAGTTCACGCAAGC SEQ ID NO: 722 CCCGCCTAGCTCACGCAAGCC SEQ ID NO: 723 CCGCCTAGCTTACGCAAGCCG SEQ ID NO: 724 CGCCTAGCTCTCGCAAGCCGC SEQ ID NO: 725 GCCTAGCTCATGCAAGCCGCC SEQ ID NO: 726 CCTAGCTCACTCAAGCCGCCA SEQ ID NO: 727 CTAGCTCACGTAAGCCGCCAA SEQ ID NO: 728 TAGCTCACGCTAGCCGCCAAC SEQ ID NO: 729 AGCTCACGCATGCCGCCAACG SEQ ID NO: 730 GCTCACGCAATCCGCCAACGC SEQ ID NO: 731 ATATAGTTTCGTCATTCATC SEQ ID NO: 732 TACATTGCCCATGTAATTAA SEQ ID NO: 733 ATATAGTTTCGTCATTCATC SEQ ID NO: 734 TACATTGCCCATGTAATTAA SEQ ID NO: 735 AGATAGTTTTGTCATTCATC SEQ ID NO: 736 AGATAGTTTCTTCATTCATC SEQ ID NO: 737 AGATAGTTTCGTCATTCATC SEQ ID NO: 738 AGATAGTTTCGTTATTCATC SEQ ID NO: 739 CTCACGCAAGTCGCCAACGCC SEQ ID NO: 740 TCACGCAAGCTGCCAACGCCT SEQ ID NO: 741 CACGCAAGCCTCCAACGCCTC SEQ ID NO: 742 ACGCAAGCCGTCAACGCCTCT SEQ ID NO: 743 CGCAAGCCGCTAACGCCTCTC SEQ ID NO: 744 GCAAGCCGCCTACGCCTCTCC SEQ ID NO: 745 CAAGCCGCCATCGCCTCTCCC SEQ ID NO: 746 AAGCCGCCAATGCCTCTCCCC SEQ ID NO: 747 AGCCGCCAACTCCTCTCCCCC SEQ ID NO: 748 GCCGCCAACGTCTCTCCCCCT SEQ ID NO: 749 CCGCCAACGCTTCTCCCCCTC SEQ ID NO: 750 CGCCAACGCCTCTCCCCCTCT SEQ ID NO: 751 GCCAACGCCTTTCCCCCTCTC SEQ ID NO: 752 CCAACGCCTCTCCCCCTCTCA SEQ ID NO: 753 CAACGCCTCTTCCCCTCTCAT SEQ ID NO: 754 AACGCCTCTCTCCCTCTCATC SEQ ID NO: 755 ACGCCTCTCCTCCTCTCATCC SEQ ID NO: 756 CGCCTCTCCCTCTCTCATCCA SEQ ID NO: 757 CCCCGCCTAGGTCACGCAAGC SEQ ID NO: 758 CCCGCCTAGCGCACGCAAGCC SEQ ID NO: 759 CCGCCTAGCTGACGCAAGCCG SEQ ID NO: 760 CGCCTAGCTCGCGCAAGCCGC SEQ ID NO: 761 GCCTAGCTCAGGCAAGCCGCC SEQ ID NO: 762 CCTAGCTCACGCAAGCCGCCA SEQ ID NO: 763 CTAGCTCACGGAAGCCGCCAA SEQ ID NO: 764 TAGCTCACGCGAGCCGCCAAC SEQ ID NO: 765 AGCTCACGCAGGCCGCCAACG SEQ ID NO: 766 GCTCACGCAAGCCGCCAACGC SEQ ID NO: 767 TACATTGCCCATGTAATTAA SEQ ID NO: 768 ATATAGTTTCGTCATTCATC SEQ ID NO: 769 TACATTGCCCATGTAATTAA SEQ ID NO: 770 ATATAGTTTCGTCATTCATC SEQ ID NO: 771 AGATAGTTTGGTCATTCATC SEQ ID NO: 772 AGATAGTTTCGTCATTCATC SEQ ID NO: 773 AGATAGTTTCGGCATTCATC SEQ ID NO: 774 AGATAGTTTCGTGATTCATC SEQ ID NO: 775 CTCACGCAAGGCGCCAACGCC SEQ ID NO: 776 TCACGCAAGCGGCCAACGCCT SEQ ID NO: 777 CACGCAAGCCGCCAACGCCTC SEQ ID NO: 778 ACGCAAGCCGGCAACGCCTCT SEQ ID NO: 779 CGCAAGCCGCGAACGCCTCTC SEQ ID NO: 780 GCAAGCCGCCGACGCCTCTCC SEQ ID NO: 781 CAAGCCGCCAGCGCCTCTCCC SEQ ID NO: 782 AAGCCGCCAAGGCCTCTCCCC SEQ ID NO: 783 AGCCGCCAACGCCTCTCCCCC SEQ ID NO: 784 GCCGCCAACGGCTCTCCCCCT SEQ ID NO: 785 CCGCCAACGCGTCTCCCCCTC SEQ ID NO: 786 CGCCAACGCCGCTCCCCCTCT SEQ ID NO: 787 GCCAACGCCTGTCCCCCTCTC SEQ ID NO: 788 CCAACGCCTCGCCCCCTCTCA SEQ ID NO: 789 CAACGCCTCTGCCCCTCTCAT SEQ ID NO: 790 AACGCCTCTCGCCCTCTCATC SEQ ID NO: 791 ACGCCTCTCCGCCTCTCATCC SEQ ID NO: 792 CGCCTCTCCCGCTCTCATCCA SEQ ID NO: 793 CCCCGCCTAGCTCACGCAAGC SEQ ID NO: 794 CCCGCCTAGCCCACGCAAGCC SEQ ID NO: 795 CCGCCTAGCTCACGCAAGCCG SEQ ID NO: 796 CGCCTAGCTCCCGCAAGCCGC SEQ ID NO: 797 GCCTAGCTCACGCAAGCCGCC SEQ ID NO: 798 CCTAGCTCACCCAAGCCGCCA SEQ ID NO: 799 CTAGCTCACGCAAGCCGCCAA SEQ ID NO: 800 TAGCTCACGCCAGCCGCCAAC SEQ ID NO: 801 AGCTCACGCACGCCGCCAACG SEQ ID NO: 802 GCTCACGCAACCCGCCAACGC SEQ ID NO: 803 ATATAGTTTCGTCATTCATC SEQ ID NO: 804 TACATTGCCCATGTAATTAA SEQ ID NO: 805 ATATAGTTTCGTCATTCATC SEQ ID NO: 806 TACATTGCCCATGTAATTAA SEQ ID NO: 807 AGATAGTTTCGTCATTCATC SEQ ID NO: 808 AGATAGTTTCCTCATTCATC SEQ ID NO: 809 AGATAGTTTCGCCATTCATC SEQ ID NO: 810 AGATAGTTTCGTCATTCATC SEQ ID NO: 811 CTCACGCAAGCCGCCAACGCC SEQ ID NO: 812 TCACGCAAGCCGCCAACGCCT SEQ ID NO: 813 CACGCAAGCCCCCAACGCCTC SEQ ID NO: 814 ACGCAAGCCGCCAACGCCTCT SEQ ID NO: 815 CGCAAGCCGCCAACGCCTCTC SEQ ID NO: 816 GCAAGCCGCCCACGCCTCTCC SEQ ID NO: 817 CAAGCCGCCACCGCCTCTCCC SEQ ID NO: 818 AAGCCGCCAACGCCTCTCCCC SEQ ID NO: 819 AGCCGCCAACCCCTCTCCCCC SEQ ID NO: 820 GCCGCCAACGCCTCTCCCCCT SEQ ID NO: 821 CCGCCAACGCCTCTCCCCCTC SEQ ID NO: 822 CGCCAACGCCCCTCCCCCTCT SEQ ID NO: 823 GCCAACGCCTCTCCCCCTCTC SEQ ID NO: 824 CCAACGCCTCCCCCCCTCTCA SEQ ID NO: 825 CAACGCCTCTCCCCCTCTCAT SEQ ID NO: 826 AACGCCTCTCCCCCTCTCATC SEQ ID NO: 827 ACGCCTCTCCCCCTCTCATCC SEQ ID NO: 828 CGCCTCTCCCCCTCTCATCCA SEQ ID NO: 829 CCCCGCCTAGATCACGCAAGC SEQ ID NO: 830 CCCGCCTAGCACACGCAAGCC SEQ ID NO: 831 CCGCCTAGCTAACGCAAGCCG SEQ ID NO: 832 CGCCTAGCTCACGCAAGCCGC SEQ ID NO: 833 GCCTAGCTCAAGCAAGCCGCC SEQ ID NO: 834 CCTAGCTCACACAAGCCGCCA SEQ ID NO: 835 CTAGCTCACGAAAGCCGCCAA SEQ ID NO: 836 TAGCTCACGCAAGCCGCCAAC SEQ ID NO: 837 AGCTCACGCAAGCCGCCAACG SEQ ID NO: 838 GCTCACGCAAACCGCCAACGC SEQ ID NO: 839 TACATTGCCCATGTAATTAA SEQ ID NO: 840 ATATAGTTTCGTCATTCATC SEQ ID NO: 841 TACATTGCCCATGTAATTAA SEQ ID NO: 842 ATATAGTTTCGTCATTCATC SEQ ID NO: 843 AGATAGTTTAGTCATTCATC SEQ ID NO: 844 AGATAGTTTCATCATTCATC SEQ ID NO: 845 AGATAGTTTCGACATTCATC SEQ ID NO: 846 AGATAGTTTCGTAATTCATC SEQ ID NO: 847 CTCACGCAAGACGCCAACGCC SEQ ID NO: 848 TCACGCAAGCAGCCAACGCCT SEQ ID NO: 849 CACGCAAGCCACCAACGCCTC SEQ ID NO: 850 ACGCAAGCCGACAACGCCTCT SEQ ID NO: 851 CGCAAGCCGCAAACGCCTCTC SEQ ID NO: 852 GCAAGCCGCCAACGCCTCTCC SEQ ID NO: 853 CAAGCCGCCAACGCCTCTCCC SEQ ID NO: 854 AAGCCGCCAAAGCCTCTCCCC SEQ ID NO: 855 AGCCGCCAACACCTCTCCCCC SEQ ID NO: 856 GCCGCCAACGACTCTCCCCCT SEQ ID NO: 857 CCGCCAACGCATCTCCCCCTC SEQ ID NO: 858 CGCCAACGCCACTCCCCCTCT SEQ ID NO: 859 GCCAACGCCTATCCCCCTCTC SEQ ID NO: 860 CCAACGCCTCACCCCCTCTCA SEQ ID NO: 861 CAACGCCTCTACCCCTCTCAT SEQ ID NO: 862 AACGCCTCTCACCCTCTCATC SEQ ID NO: 863 ACGCCTCTCCACCTCTCATCC SEQ ID NO: 864 CGCCTCTCCCACTCTCATCCA SEQ ID NO: 865 GCCTCTCCCCTTCTCATCCAT SEQ ID NO: 866 CCTCTCCCCCTCTCATCCATC SEQ ID NO: 867 CTCTCCCCCTTTCATCCATCG SEQ ID NO: 868 TCTCCCCCTCTCATCCATCGC SEQ ID NO: 869 CTCCCCCTCTTATCCATCGCC SEQ ID NO: 870 TCCCCCTCTCTTCCATCGCCC SEQ ID NO: 871 CCCCCTCTCATCCATCGCCCG SEQ ID NO: 872 ATATAGTTTCGTCATTCATC SEQ ID NO: 873 TACATTGCCCATGTAATTAA SEQ ID NO: 874 ATATAGTTTCGTCATTCATC SEQ ID NO: 875 TACATTGCCCATGTAATTAA SEQ ID NO: 876 AGATAGTTTTGTCATTCATC SEQ ID NO: 877 AGATAGTTTCTTCATTCATC SEQ ID NO: 878 AGATAGTTTCGTCATTCATC SEQ ID NO: 879 AGATAGTTTCGTTATTCATC SEQ ID NO: 880 CCCCTCTCATTCATCGCCCGC SEQ ID NO: 881 CCCTCTCATCTATCGCCCGCC SEQ ID NO: 882 CCTCTCATCCTTCGCCCGCCG SEQ ID NO: 883 CTCTCATCCATCGCCCGCCGC SEQ ID NO: 884 TCTCATCCATTGCCCGCCGCC SEQ ID NO: 885 CTCATCCATCTCCCGCCGCCC SEQ ID NO: 886 TCATCCATCGTCCGCCGCCCC SEQ ID NO: 887 CATCCATCGCTCGCCGCCCCT SEQ ID NO: 888 ATCCATCGCCTGCCGCCCCTC SEQ ID NO: 889 TCCATCGCCCTCCGCCCCTCA SEQ ID NO: 890 CCATCGCCCGTCGCCCCTCAT SEQ ID NO: 891 CATCGCCCGCTGCCCCTCATC SEQ ID NO: 892 ATCGCCCGCCTCCCCTCATCA SEQ ID NO: 893 TCGCCCGCCGTCCCTCATCAT SEQ ID NO: 894 CGCCCGCCGCTCCTCATCATA SEQ ID NO: 895 GCCCGCCGCCTCTCATCATAC SEQ ID NO: 896 CCCGCCGCCCTTCATCATACC SEQ ID NO: 897 CCGCCGCCCCTCATCATACCT SEQ ID NO: 898 CGCCGCCCCTTATCATACCTC SEQ ID NO: 899 GCCGCCCCTCTTCATACCTCA SEQ ID NO: 900 CCGCCCCTCATCATACCTCAG SEQ ID NO: 901 GCCTCTCCCCGTCTCATCCAT SEQ ID NO: 902 CCTCTCCCCCGCTCATCCATC SEQ ID NO: 903 CTCTCCCCCTGTCATCCATCG SEQ ID NO: 904 TCTCCCCCTCGCATCCATCGC SEQ ID NO: 905 CTCCCCCTCTGATCCATCGCC SEQ ID NO: 906 TCCCCCTCTCGTCCATCGCCC SEQ ID NO: 907 CCCCCTCTCAGCCATCGCCCG SEQ ID NO: 908 TACATTGCCCATGTAATTAA SEQ ID NO: 909 ATATAGTTTCGTCATTCATC SEQ ID NO: 910 TACATTGCCCATGTAATTAA SEQ ID NO: 911 ATATAGTTTCGTCATTCATC SEQ ID NO: 912 AGATAGTTTGGTCATTCATC SEQ ID NO: 913 AGATAGTTTCGTCATTCATC SEQ ID NO: 914 AGATAGTTTCGGCATTCATC SEQ ID NO: 915 AGATAGTTTCGTGATTCATC SEQ ID NO: 916 CCCCTCTCATGCATCGCCCGC SEQ ID NO: 917 CCCTCTCATCGATCGCCCGCC SEQ ID NO: 918 CCTCTCATCCGTCGCCCGCCG SEQ ID NO: 919 CTCTCATCCAGCGCCCGCCGC SEQ ID NO: 920 TCTCATCCATGGCCCGCCGCC SEQ ID NO: 921 CTCATCCATCGCCCGCCGCCC SEQ ID NO: 922 TCATCCATCGGCCGCCGCCCC SEQ ID NO: 923 CATCCATCGCGCGCCGCCCCT SEQ ID NO: 924 ATCCATCGCCGGCCGCCCCTC SEQ ID NO: 925 TCCATCGCCCGCCGCCCCTCA SEQ ID NO: 926 CCATCGCCCGGCGCCCCTCAT SEQ ID NO: 927 CATCGCCCGCGGCCCCTCATC SEQ ID NO: 928 ATCGCCCGCCGCCCCTCATCA SEQ ID NO: 929 TCGCCCGCCGGCCCTCATCAT SEQ ID NO: 930 CGCCCGCCGCGCCTCATCATA SEQ ID NO: 931 GCCCGCCGCCGCTCATCATAC SEQ ID NO: 932 CCCGCCGCCCGTCATCATACC SEQ ID NO: 933 CCGCCGCCCCGCATCATACCT SEQ ID NO: 934 CGCCGCCCCTGATCATACCTC SEQ ID NO: 935 GCCGCCCCTCGTCATACCTCA SEQ ID NO: 936 CCGCCCCTCAGCATACCTCAG SEQ ID NO: 937 GCCTCTCCCCCTCTCATCCAT SEQ ID NO: 938 CCTCTCCCCCCCTCATCCATC SEQ ID NO: 939 CTCTCCCCCTCTCATCCATCG SEQ ID NO: 940 TCTCCCCCTCCCATCCATCGC SEQ ID NO: 941 CTCCCCCTCTCATCCATCGCC SEQ ID NO: 942 TCCCCCTCTCCTCCATCGCCC SEQ ID NO: 943 CCCCCTCTCACCCATCGCCCG SEQ ID NO: 944 ATATAGTTTCGTCATTCATC SEQ ID NO: 945 TACATTGCCCATGTAATTAA SEQ ID NO: 946 ATATAGTTTCGTCATTCATC SEQ ID NO: 947 TACATTGCCCATGTAATTAA SEQ ID NO: 948 AGATAGTTTCGTCATTCATC SEQ ID NO: 949 AGATAGTTTCCTCATTCATC SEQ ID NO: 950 AGATAGTTTCGCCATTCATC SEQ ID NO: 951 AGATAGTTTCGTCATTCATC SEQ ID NO: 952 CCCCTCTCATCCATCGCCCGC SEQ ID NO: 953 CCCTCTCATCCATCGCCCGCC SEQ ID NO: 954 CCTCTCATCCCTCGCCCGCCG SEQ ID NO: 955 CTCTCATCCACCGCCCGCCGC SEQ ID NO: 956 TCTCATCCATCGCCCGCCGCC SEQ ID NO: 957 CTCATCCATCCCCCGCCGCCC SEQ ID NO: 958 TCATCCATCGCCCGCCGCCCC SEQ ID NO: 959 CATCCATCGCCCGCCGCCCCT SEQ ID NO: 960 ATCCATCGCCCGCCGCCCCTC SEQ ID NO: 961 TCCATCGCCCCCCGCCCCTCA SEQ ID NO: 962 CCATCGCCCGCCGCCCCTCAT SEQ ID NO: 963 CATCGCCCGCCGCCCCTCATC SEQ ID NO: 964 ATCGCCCGCCCCCCCTCATCA SEQ ID NO: 965 TCGCCCGCCGCCCCTCATCAT SEQ ID NO: 966 CGCCCGCCGCCCCTCATCATA SEQ ID NO: 967 GCCCGCCGCCCCTCATCATAC SEQ ID NO: 968 CCCGCCGCCCCTCATCATACC SEQ ID NO: 969 CCGCCGCCCCCCATCATACCT SEQ ID NO: 970 CGCCGCCCCTCATCATACCTC SEQ ID NO: 971 GCCGCCCCTCCTCATACCTCA SEQ ID NO: 972 CCGCCCCTCACCATACCTCAG SEQ ID NO: 973 GCCTCTCCCCATCTCATCCAT SEQ ID NO: 974 CCTCTCCCCCACTCATCCATC SEQ ID NO: 975 CTCTCCCCCTATCATCCATCG SEQ ID NO: 976 TCTCCCCCTCACATCCATCGC SEQ ID NO: 977 CTCCCCCTCTAATCCATCGCC SEQ ID NO: 978 TCCCCCTCTCATCCATCGCCC SEQ ID NO: 979 CCCCCTCTCAACCATCGCCCG SEQ ID NO: 980 TACATTGCCCATGTAATTAA SEQ ID NO: 981 ATATAGTTTCGTCATTCATC SEQ ID NO: 982 TACATTGCCCATGTAATTAA SEQ ID NO: 983 ATATAGTTTCGTCATTCATC SEQ ID NO: 984 AGATAGTTTAGTCATTCATC SEQ ID NO: 985 AGATAGTTTCATCATTCATC SEQ ID NO: 986 AGATAGTTTCGACATTCATC SEQ ID NO: 987 AGATAGTTTCGTAATTCATC SEQ ID NO: 988 CCCCTCTCATACATCGCCCGC SEQ ID NO: 989 CCCTCTCATCAATCGCCCGCC SEQ ID NO: 990 CCTCTCATCCATCGCCCGCCG SEQ ID NO: 991 CTCTCATCCAACGCCCGCCGC SEQ ID NO: 992 TCTCATCCATAGCCCGCCGCC SEQ ID NO: 993 CTCATCCATCACCCGCCGCCC SEQ ID NO: 994 TCATCCATCGACCGCCGCCCC SEQ ID NO: 995 CATCCATCGCACGCCGCCCCT SEQ ID NO: 996 ATCCATCGCCAGCCGCCCCTC SEQ ID NO: 997 TCCATCGCCCACCGCCCCTCA SEQ ID NO: 998 CCATCGCCCGACGCCCCTCAT SEQ ID NO: 999 CATCGCCCGCAGCCCCTCATC SEQ ID NO: 1000 ATCGCCCGCCACCCCTCATCA SEQ ID NO: 1001 TCGCCCGCCGACCCTCATCAT SEQ ID NO: 1002 CGCCCGCCGCACCTCATCATA SEQ ID NO: 1003 GCCCGCCGCCACTCATCATAC SEQ ID NO: 1004 CCCGCCGCCCATCATCATACC SEQ ID NO: 1005 CCGCCGCCCCACATCATACCT SEQ ID NO: 1006 CGCCGCCCCTAATCATACCTC SEQ ID NO: 1007 GCCGCCCCTCATCATACCTCA SEQ ID NO: 1008 CCGCCCCTCAACATACCTCAG SEQ ID NO: 1009 CGCCCCTCATTATACCTCAGC SEQ ID NO: 1010 GCCCCTCATCTTACCTCAGCC SEQ ID NO: 1011 CCCCTCATCATACCTCAGCCG SEQ ID NO: 1012 CCCTCATCATTCCTCAGCCGC SEQ ID NO: 1013 ATATAGTTTCGTCATTCATC SEQ ID NO: 1014 TACATTGCCCATGTAATTAA SEQ ID NO: 1015 ATATAGTTTCGTCATTCATC SEQ ID NO: 1016 TACATTGCCCATGTAATTAA SEQ ID NO: 1017 AGATAGTTTTGTCATTCATC SEQ ID NO: 1018 AGATAGTTTCTTCATTCATC SEQ ID NO: 1019 AGATAGTTTCGTCATTCATC SEQ ID NO: 1020 AGATAGTTTCGTTATTCATC SEQ ID NO: 1021 CCTCATCATATCTCAGCCGCC SEQ ID NO: 1022 CTCATCATACTTCAGCCGCCG SEQ ID NO: 1023 TCATCATACCTCAGCCGCCGC SEQ ID NO: 1024 CATCATACCTTAGCCGCCGCC SEQ ID NO: 1025 ATCATACCTCTGCCGCCGCCC SEQ ID NO: 1026 TCATACCTCATCCGCCGCCCC SEQ ID NO: 1027 CATACCTCAGTCGCCGCCCCT SEQ ID NO: 1028 ATACCTCAGCTGCCGCCCCTC SEQ ID NO: 1029 TACCTCAGCCTCCGCCCCTCA SEQ ID NO: 1030 ACCTCAGCCGTCGCCCCTCAT SEQ ID NO: 1031 CCTCAGCCGCTGCCCCTCATC SEQ ID NO: 1032 CTCAGCCGCCTCCCCTCATCA SEQ ID NO: 1033 TCAGCCGCCGTCCCTCATCAT SEQ ID NO: 1034 CAGCCGCCGCTCCTCATCATA SEQ ID NO: 1035 AGCCGCCGCCTCTCATCATAC SEQ ID NO: 1036 GCCGCCGCCCTTCATCATACC SEQ ID NO: 1037 CCGCCGCCCCTCATCATACCT SEQ ID NO: 1038 CGCCGCCCCTTATCATACCTC SEQ ID NO: 1039 GCCGCCCCTCTTCATACCTCA SEQ ID NO: 1040 CCGCCCCTCATCATACCTCAA SEQ ID NO: 1041 CGCCCCTCATTATACCTCAAA SEQ ID NO: 1042 GCCCCTCATCTTACCTCAAAA SEQ ID NO: 1043 CCCCTCATCATACCTCAAAAG SEQ ID NO: 1044 CCCTCATCATTCCTCAAAAGC SEQ ID NO: 1045 CGCCCCTCATGATACCTCAGC SEQ ID NO: 1046 GCCCCTCATCGTACCTCAGCC SEQ ID NO: 1047 CCCCTCATCAGACCTCAGCCG SEQ ID NO: 1048 CCCTCATCATGCCTCAGCCGC SEQ ID NO: 1049 TACATTGCCCATGTAATTAA SEQ ID NO: 1050 ATATAGTTTCGTCATTCATC SEQ ID NO: 1051 TACATTGCCCATGTAATTAA SEQ ID NO: 1052 ATATAGTTTCGTCATTCATC SEQ ID NO: 1053 AGATAGTTTGGTCATTCATC SEQ ID NO: 1054 AGATAGTTTCGTCATTCATC SEQ ID NO: 1055 AGATAGTTTCGGCATTCATC SEQ ID NO: 1056 AGATAGTTTCGTGATTCATC SEQ ID NO: 1057 CCTCATCATAGCTCAGCCGCC SEQ ID NO: 1058 CTCATCATACGTCAGCCGCCG SEQ ID NO: 1059 TCATCATACCGCAGCCGCCGC SEQ ID NO: 1060 CATCATACCTGAGCCGCCGCC SEQ ID NO: 1061 ATCATACCTCGGCCGCCGCCC SEQ ID NO: 1062 TCATACCTCAGCCGCCGCCCC SEQ ID NO: 1063 CATACCTCAGGCGCCGCCCCT SEQ ID NO: 1064 ATACCTCAGCGGCCGCCCCTC SEQ ID NO: 1065 TACCTCAGCCGCCGCCCCTCA SEQ ID NO: 1066 ACCTCAGCCGGCGCCCCTCAT SEQ ID NO: 1067 CCTCAGCCGCGGCCCCTCATC SEQ ID NO: 1068 CTCAGCCGCCGCCCCTCATCA SEQ ID NO: 1069 TCAGCCGCCGGCCCTCATCAT SEQ ID NO: 1070 CAGCCGCCGCGCCTCATCATA SEQ ID NO: 1071 AGCCGCCGCCGCTCATCATAC SEQ ID NO: 1072 GCCGCCGCCCGTCATCATACC SEQ ID NO: 1073 CCGCCGCCCCGCATCATACCT SEQ ID NO: 1074 CGCCGCCCCTGATCATACCTC SEQ ID NO: 1075 GCCGCCCCTCGTCATACCTCA SEQ ID NO: 1076 CCGCCCCTCAGCATACCTCAA SEQ ID NO: 1077 CGCCCCTCATGATACCTCAAA SEQ ID NO: 1078 GCCCCTCATCGTACCTCAAAA SEQ ID NO: 1079 CCCCTCATCAGACCTCAAAAG SEQ ID NO: 1080 CCCTCATCATGCCTCAAAAGC SEQ ID NO: 1081 CGCCCCTCATCATACCTCAGC SEQ ID NO: 1082 GCCCCTCATCCTACCTCAGCC SEQ ID NO: 1083 CCCCTCATCACACCTCAGCCG SEQ ID NO: 1084 CCCTCATCATCCCTCAGCCGC SEQ ID NO: 1085 ATATAGTTTCGTCATTCATC SEQ ID NO: 1086 TACATTGCCCATGTAATTAA SEQ ID NO: 1087 ATATAGTTTCGTCATTCATC SEQ ID NO: 1088 TACATTGCCCATGTAATTAA SEQ ID NO: 1089 AGATAGTTTCGTCATTCATC SEQ ID NO: 1090 AGATAGTTTCCTCATTCATC SEQ ID NO: 1091 AGATAGTTTCGCCATTCATC SEQ ID NO: 1092 AGATAGTTTCGTCATTCATC SEQ ID NO: 1093 CCTCATCATACCTCAGCCGCC SEQ ID NO: 1094 CTCATCATACCTCAGCCGCCG SEQ ID NO: 1095 TCATCATACCCCAGCCGCCGC SEQ ID NO: 1096 CATCATACCTCAGCCGCCGCC SEQ ID NO: 1097 ATCATACCTCCGCCGCCGCCC SEQ ID NO: 1098 TCATACCTCACCCGCCGCCCC SEQ ID NO: 1099 CATACCTCAGCCGCCGCCCCT SEQ ID NO: 1100 ATACCTCAGCCGCCGCCCCTC SEQ ID NO: 1101 TACCTCAGCCCCCGCCCCTCA SEQ ID NO: 1102 ACCTCAGCCGCCGCCCCTCAT SEQ ID NO: 1103 CCTCAGCCGCCGCCCCTCATC SEQ ID NO: 1104 CTCAGCCGCCCCCCCTCATCA SEQ ID NO: 1105 TCAGCCGCCGCCCCTCATCAT SEQ ID NO: 1106 CAGCCGCCGCCCCTCATCATA SEQ ID NO: 1107 AGCCGCCGCCCCTCATCATAC SEQ ID NO: 1108 GCCGCCGCCCCTCATCATACC SEQ ID NO: 1109 CCGCCGCCCCCCATCATACCT SEQ ID NO: 1110 CGCCGCCCCTCATCATACCTC SEQ ID NO: 1111 GCCGCCCCTCCTCATACCTCA SEQ ID NO: 1112 CCGCCCCTCACCATACCTCAA SEQ ID NO: 1113 CGCCCCTCATCATACCTCAAA SEQ ID NO: 1114 GCCCCTCATCCTACCTCAAAA SEQ ID NO: 1115 CCCCTCATCACACCTCAAAAG SEQ ID NO: 1116 CCCTCATCATCCCTCAAAAGC SEQ ID NO: 1117 CGCCCCTCATAATACCTCAGC SEQ ID NO: 1118 GCCCCTCATCATACCTCAGCC SEQ ID NO: 1119 CCCCTCATCAAACCTCAGCCG SEQ ID NO: 1120 CCCTCATCATACCTCAGCCGC SEQ ID NO: 1121 TACATTGCCCATGTAATTAA SEQ ID NO: 1122 ATATAGTTTCGTCATTCATC SEQ ID NO: 1123 TACATTGCCCATGTAATTAA SEQ ID NO: 1124 ATATAGTTTCGTCATTCATC SEQ ID NO: 1125 AGATAGTTTAGTCATTCATC SEQ ID NO: 1126 AGATAGTTTCATCATTCATC SEQ ID NO: 1127 AGATAGTTTCGACATTCATC SEQ ID NO: 1128 AGATAGTTTCGTAATTCATC SEQ ID NO: 1129 CCTCATCATAACTCAGCCGCC SEQ ID NO: 1130 CTCATCATACATCAGCCGCCG SEQ ID NO: 1131 TCATCATACCACAGCCGCCGC SEQ ID NO: 1132 CATCATACCTAAGCCGCCGCC SEQ ID NO: 1133 ATCATACCTCAGCCGCCGCCC SEQ ID NO: 1134 TCATACCTCAACCGCCGCCCC SEQ ID NO: 1135 CATACCTCAGACGCCGCCCCT SEQ ID NO: 1136 ATACCTCAGCAGCCGCCCCTC SEQ ID NO: 1137 TACCTCAGCCACCGCCCCTCA SEQ ID NO: 1138 ACCTCAGCCGACGCCCCTCAT SEQ ID NO: 1139 CCTCAGCCGCAGCCCCTCATC SEQ ID NO: 1140 CTCAGCCGCCACCCCTCATCA SEQ ID NO: 1141 TCAGCCGCCGACCCTCATCAT SEQ ID NO: 1142 CAGCCGCCGCACCTCATCATA SEQ ID NO: 1143 AGCCGCCGCCACTCATCATAC SEQ ID NO: 1144 GCCGCCGCCCATCATCATACC SEQ ID NO: 1145 CCGCCGCCCCACATCATACCT SEQ ID NO: 1146 CGCCGCCCCTAATCATACCTC SEQ ID NO: 1147 GCCGCCCCTCATCATACCTCA SEQ ID NO: 1148 CCGCCCCTCAACATACCTCAA SEQ ID NO: 1149 CGCCCCTCATAATACCTCAAA SEQ ID NO: 1150 GCCCCTCATCATACCTCAAAA SEQ ID NO: 1151 CCCCTCATCAAACCTCAAAAG SEQ ID NO: 1152 CCCTCATCATACCTCAAAAGC SEQ ID NO: 1153 CCTCATCATATCTCAAAAGCC SEQ ID NO: 1154 ATATAGTTTCGTCATTCATC SEQ ID NO: 1155 TACATTGCCCATGTAATTAA SEQ ID NO: 1156 ATATAGTTTCGTCATTCATC SEQ ID NO: 1157 TACATTGCCCATGTAATTAA SEQ ID NO: 1158 AGATAGTTTTGTCATTCATC SEQ ID NO: 1159 AGATAGTTTCTTCATTCATC SEQ ID NO: 1160 AGATAGTTTCGTCATTCATC SEQ ID NO: 1161 AGATAGTTTCGTTATTCATC SEQ ID NO: 1162 CTCATCATACTTCAAAAGCCA SEQ ID NO: 1163 TCATCATACCTCAAAAGCCAA SEQ ID NO: 1164 CATCATACCTTAAAAGCCAAC SEQ ID NO: 1165 ATCATACCTCTAAAGCCAACT SEQ ID NO: 1166 TCATACCTCATAAGCCAACTA SEQ ID NO: 1167 CATACCTCAATAGCCAACTAA SEQ ID NO: 1168 ATACCTCAAATGCCAACTAAC SEQ ID NO: 1169 TACCTCAAAATCCAACTAACC SEQ ID NO: 1170 ACCTCAAAAGTCAACTAACCA SEQ ID NO: 1171 CCTCAAAAGCTAACTAACCAA SEQ ID NO: 1172 CTCAAAAGCCTACTAACCAAC SEQ ID NO: 1173 TCAAAAGCCATCTAACCAACC SEQ ID NO: 1174 CAAAAGCCAATTAACCAACCA SEQ ID NO: 1175 AAAAGCCAACTAACCAACCAA SEQ ID NO: 1176 AAAGCCAACTTACCAACCAAT SEQ ID NO: 1177 ATATAGTTTCGTCATTCATC SEQ ID NO: 1178 TACATTGCCCATGTAATTAA SEQ ID NO: 1179 ATATAGTTTCGTCATTCATC SEQ ID NO: 1180 TACATTGCCCATGTAATTAA SEQ ID NO: 1181 AGATAGTTTTGTCATTCATC SEQ ID NO: 1182 AGATAGTTTCTTCATTCATC SEQ ID NO: 1183 AGATAGTTTCGTCATTCATC SEQ ID NO: 1184 AGATAGTTTCGTTATTCATC SEQ ID NO: 1185 CCTCATCATAGCTCAAAAGCC SEQ ID NO: 1186 TACATTGCCCATGTAATTAA SEQ ID NO: 1187 ATATAGTTTCGTCATTCATC SEQ ID NO: 1188 TACATTGCCCATGTAATTAA SEQ ID NO: 1189 ATATAGTTTCGTCATTCATC SEQ ID NO: 1190 AGATAGTTTGGTCATTCATC SEQ ID NO: 1191 AGATAGTTTCGTCATTCATC SEQ ID NO: 1192 AGATAGTTTCGGCATTCATC SEQ ID NO: 1193 AGATAGTTTCGTGATTCATC SEQ ID NO: 1194 CTCATCATACGTCAAAAGCCA SEQ ID NO: 1195 TCATCATACCGCAAAAGCCAA SEQ ID NO: 1196 CATCATACCTGAAAAGCCAAC SEQ ID NO: 1197 ATCATACCTCGAAAGCCAACT SEQ ID NO: 1198 TCATACCTCAGAAGCCAACTA SEQ ID NO: 1199 CATACCTCAAGAGCCAACTAA SEQ ID NO: 1200 ATACCTCAAAGGCCAACTAAC SEQ ID NO: 1201 TACCTCAAAAGCCAACTAACC SEQ ID NO: 1202 ACCTCAAAAGGCAACTAACCA SEQ ID NO: 1203 CCTCAAAAGCGAACTAACCAA SEQ ID NO: 1204 CTCAAAAGCCGACTAACCAAC SEQ ID NO: 1205 TCAAAAGCCAGCTAACCAACC SEQ ID NO: 1206 CAAAAGCCAAGTAACCAACCA SEQ ID NO: 1207 AAAAGCCAACGAACCAACCAA SEQ ID NO: 1208 AAAGCCAACTGACCAACCAAT SEQ ID NO: 1209 TACATTGCCCATGTAATTAA SEQ ID NO: 1210 ATATAGTTTCGTCATTCATC SEQ ID NO: 1211 TACATTGCCCATGTAATTAA SEQ ID NO: 1212 ATATAGTTTCGTCATTCATC SEQ ID NO: 1213 AGATAGTTTGGTCATTCATC SEQ ID NO: 1214 AGATAGTTTCGTCATTCATC SEQ ID NO: 1215 AGATAGTTTCGGCATTCATC SEQ ID NO: 1216 AGATAGTTTCGTGATTCATC SEQ ID NO: 1217 CCTCATCATACCTCAAAAGCC SEQ ID NO: 1218 ATATAGTTTCGTCATTCATC SEQ ID NO: 1219 TACATTGCCCATGTAATTAA SEQ ID NO: 1220 ATATAGTTTCGTCATTCATC SEQ ID NO: 1221 TACATTGCCCATGTAATTAA SEQ ID NO: 1222 AGATAGTTTCGTCATTCATC SEQ ID NO: 1223 AGATAGTTTCCTCATTCATC SEQ ID NO: 1224 AGATAGTTTCGCCATTCATC SEQ ID NO: 1225 AGATAGTTTCGTCATTCATC SEQ ID NO: 1226 CTCATCATACCTCAAAAGCCA SEQ ID NO: 1227 TCATCATACCCCAAAAGCCAA SEQ ID NO: 1228 CATCATACCTCAAAAGCCAAC SEQ ID NO: 1229 ATCATACCTCCAAAGCCAACT SEQ ID NO: 1230 TCATACCTCACAAGCCAACTA SEQ ID NO: 1231 CATACCTCAACAGCCAACTAA SEQ ID NO: 1232 ATACCTCAAACGCCAACTAAC SEQ ID NO: 1233 TACCTCAAAACCCAACTAACC SEQ ID NO: 1234 ACCTCAAAAGCCAACTAACCA SEQ ID NO: 1235 CCTCAAAAGCCAACTAACCAA SEQ ID NO: 1236 CTCAAAAGCCCACTAACCAAC SEQ ID NO: 1237 TCAAAAGCCACCTAACCAACC SEQ ID NO: 1238 CAAAAGCCAACTAACCAACCA SEQ ID NO: 1239 AAAAGCCAACCAACCAACCAA SEQ ID NO: 1240 AAAGCCAACTCACCAACCAAT SEQ ID NO: 1241 ATATAGTTTCGTCATTCATC SEQ ID NO: 1242 TACATTGCCCATGTAATTAA SEQ ID NO: 1243 ATATAGTTTCGTCATTCATC SEQ ID NO: 1244 TACATTGCCCATGTAATTAA SEQ ID NO: 1245 AGATAGTTTCGTCATTCATC SEQ ID NO: 1246 AGATAGTTTCCTCATTCATC SEQ ID NO: 1247 AGATAGTTTCGCCATTCATC SEQ ID NO: 1248 AGATAGTTTCGTCATTCATC SEQ ID NO: 1249 CCTCATCATAACTCAAAAGCC SEQ ID NO: 1250 TACATTGCCCATGTAATTAA SEQ ID NO: 1251 ATATAGTTTCGTCATTCATC SEQ ID NO: 1252 TACATTGCCCATGTAATTAA SEQ ID NO: 1253 ATATAGTTTCGTCATTCATC SEQ ID NO: 1254 AGATAGTTTAGTCATTCATC SEQ ID NO: 1255 AGATAGTTTCATCATTCATC SEQ ID NO: 1256 AGATAGTTTCGACATTCATC SEQ ID NO: 1257 AGATAGTTTCGTAATTCATC SEQ ID NO: 1258 CTCATCATACATCAAAAGCCA SEQ ID NO: 1259 TCATCATACCACAAAAGCCAA SEQ ID NO: 1260 CATCATACCTAAAAAGCCAAC SEQ ID NO: 1261 ATCATACCTCAAAAGCCAACT SEQ ID NO: 1262 TCATACCTCAAAAGCCAACTA SEQ ID NO: 1263 CATACCTCAAAAGCCAACTAA SEQ ID NO: 1264 ATACCTCAAAAGCCAACTAAC SEQ ID NO: 1265 TACCTCAAAAACCAACTAACC SEQ ID NO: 1266 ACCTCAAAAGACAACTAACCA SEQ ID NO: 1267 CCTCAAAAGCAAACTAACCAA SEQ ID NO: 1268 CTCAAAAGCCAACTAACCAAC SEQ ID NO: 1269 TCAAAAGCCAACTAACCAACC SEQ ID NO: 1270 CAAAAGCCAAATAACCAACCA SEQ ID NO: 1271 AAAAGCCAACAAACCAACCAA SEQ ID NO: 1272 AAAGCCAACTAACCAACCAAT SEQ ID NO: 1273 TACATTGCCCATGTAATTAA SEQ ID NO: 1274 ATATAGTTTCGTCATTCATC SEQ ID NO: 1275 TACATTGCCCATGTAATTAA SEQ ID NO: 1276 ATATAGTTTCGTCATTCATC SEQ ID NO: 1277 AGATAGTTTAGTCATTCATC SEQ ID NO: 1278 AGATAGTTTCATCATTCATC SEQ ID NO: 1279 AGATAGTTTCGACATTCATC SEQ ID NO: 1280 AGATAGTTTCGTAATTCATC

[0058] Procedure for Probe Design

[0059] The design of a probe begins with the input of a sequence file into a computer in the five prime to three prime direction. The sequence file is then converted to account for sodium bisulfite treatment. The complementary sequence of the converted sequence file is then is then generated in the three prime to five prime direction.

[0060] A parent probe list is then created from the complementary sequence. This is accomplished by standard re-sequencing, where every base is queried. For this method the first probe starts at position X, and extend a number of bases, N. The next probe starts at position X+1, and extends N bases also. A second method to create the parent probe set is to identify all CpG dinucleotides and only create probes with a CpG dinucleotide in the middle.

[0061] Once prepared, the parent probe list is filtered to remove probes that are deemed not to be suitable for re-sequencing analysis. Factors such as low sequence complexity are taken into account. Each parent probe is used as a template to create new probes to query for possible changes at a particular position in the reference sequence. Each parent probe generates at least three new probes, one for each single nucleotide polymorphism at the central base. The parent probe and daughter probes created from it represent the position query probe partners. Additional position query probe partners may be required if multiple CpG islands are on one probe. In this case every possible combination of methylation sites from the parent probe must be created. This creates a list of sub parent probes each of whose central position is then altered to represent all possible single nucleotide polymorphisms. The collection of these probes are that position's position query probe partners.

[0062] Once the complete set of position query probe partners has been calculated, a file is generated containing all the partners for each position in the reference sequence, or those designated by the user for interrogation. A probe set generated in this manner for a portion of p16 is attached as Appendix 1.

[0063] Sodium Bisulfite Treatment Protocol

[0064] The concentration of DNA used in this protocol is 1 μg of DNA per 10 μl of sample. Samples are prepared in an autoclaved tube with 1 μg of DNA diluted to 50 μl using autoclaved water. 5.5 μl of 2M sodium hydroxide (3.6 g in 45 ml of water) is then added and the sample is maintained at 37° C. for ten minutes in a water bath. The sample tube is removed from the water bath and centrifuged. 30 μl of freshly prepared hydroquinone solution (55 mg in 50 ml of water) is added to the sample tube and the sample becomes yellow. 520 μl of freshly prepared sodium bisulfite solution (3.76 g in 10 ml of water) is then added and the resulting solution is mixed well. The sample tube is then sealed with parafilm and placed in a water bath at 60° C. for 16 hours. The tubes are removed from the water bath and the sample purified using the Wizard DNA resin (Promega) according to the manufacturer's protocol. The DNA is eluted with 50 μl of water to which is added 8.25 μl of 2M sodium hydroxide solution. The DNA is then precipitated using ethanol and a glycogen carrier. The precipitated DNA is then resuspended in 200 μl of water.

[0065] Protocol for PCR Amplification of 145 bp Region of the Promoter for p16

[0066] The primers listed below are examples of those used for the amplification. Primer Sequences: 5′ (Cy3/Cy5) GTTTTCCCAGTCACGACTTGGTTGGTTATTAGAGGGTGG 3′ (SEQ ID NO.: 1281) 5′ (Cy3/Cy5) AAACAGCTATGACCATGACCATAACCAACCAATCAACC 3′ (SEQ ID NO.: 1282) The entire 145 base sequence: 5′CTGGCTG GTCACCAGAGGGTGGGGCGG ACCGAGTGCG CTCGGCGGCT (SEQ ID NO.: 1283) GCGGAGAGGG GTAGAGCAGG CAGCGGGCGGCGGGGAGCAG CATGGAGCCG GCGGCGGGGA GCAGCATGGA GCCTTCGGCT GACTGGCTGG CCACGGC3′

[0067] The following procedure is typically done 50 times, and the resulting material combined to form a single sample. Each amplification is accomplished by adding 3.2 μl of dNTP mixture (1.25 μM in each base), 2.5 μl of 10×PCR buffer, 1 μl of primer mixture (25 μM for each primer), 17 μl of water, 0.2 μl Taq polymerase (5 units/μl) and 1 μl of template DNA from the bisulfite treatment protocol described above.

[0068] The thermocycler is then programmed to 95° C. for 12 minutes. This is followed by two cycles of treatment at 94° C. for 20 seconds, 66° C. for 40 seconds and 72° C. for 20 seconds with touchdown of −1° C. This is followed by 35 cycles of treatment at 94° C. for 20 seconds, 66° C. for 30 seconds and 72° C. for 20 seconds with touchdown of −1° C. The sample is then kept at 72° C. got 7 minutes and stored at 4° C.

EXAMPLE 2 Analysis of Methylation of a Region of the Promoter for the Tumor Suppressor Gene p16 with Oligonucleotide Arrays

[0069] An example of a method for mapping individual sites of CpG methylation in genomic DNA is further presented herein. The method of the present invention allows parallel and simultaneous analysis of many individual potential sites of methylation in widely separated regions of the genome.

[0070] Array Fabrication

[0071] Corning 1″×3″ glass microscope slides were cleaned and coated with 3-glycidoxypropyltrimethoxysilane (Aldrich) and polyethlyeneglycol (M_(a) 300, Aldrich) as described by Maskos and Southern. Slides were stored in a dessicator at room temperature until use. In preparation for microarray fabrication, the synthesis area of a slide was reacted with a 1:1 (vol:vol) mixture of 0.1 M protected linker phosphoramidite (MeNPOC-hexaethylene glycol β-cyanoethyl phosphoramidite) and tetrazole in acetonitrile (Annovis, Aston, Pa.). The mixture was allowed to react for two minutes with the glass surface and then washed with acetonitrile.

[0072] An array of oligonucleotide probes was synthesized in situ on the resulting surface using light directed phosphoramidite synthesis. MenPOC-protected phosphoramidites were used in the synthesis. Light for each photochemical deprotection step was spatially addressed with a Texas Instruments Digital Light Processor (DLP™). The DLP was illuminated with the 365 nm peak from a 200 W Hg/Xe arc lamp. Illumination of the DLP and projection of the reflected image were accomplished with a custom optical system designed by Brilliant Technologies (Denton, Tex.). The image of the DLP was projected onto the reactive surface without magnification. The DLP was coordinated with a home-built fluidics system for automated DNA synthesis. Custom software generated the patterns of illumination required to fabricate the desired array of oligonucleotides. Final deprotection of the synthesized array was with a 1:1 (vol:vol) solution of ethylenediamine and ethanol for two hours at room temperature.

[0073] Preparation of DNA and Amplification of Promoter Regions

[0074] Cell lines H1299 and H69 were established as described by Phelps and co-workers (Phelps R, Johnson B, Ihde D, et al., NCI-Navy medical oncology branch cell line data base, Journal of Cellular Biochemistry Supplement. 24: 32-91, 1996) and have been deposited in the American Type Culture Collection. The cells were cultured in RPMI 1640 (Invitrogen) supplemented with 5% fetal bovine serum. Genomic DNA was purified from these cell lines as described by Fong et al. (Fong L, Zimmerman P, and Smith P, Correlation of loss of heterozygosity at 11 p with tumour progression and survival in non-small cell lung cancer, Genes, Chromosomes, Cancer. 10: 183-189, 1994). The extracted, purified DNA was treated with sodium bisulfite. Thep16 promoter region was amplified in a PCR reaction using 50 ng sodium bisulfite-treated genomic DNA as template and the following primers: 5′[Cy3 or biotin] TTAGAGGATTTGAGGGAT3′ (SEQ ID NO.: 1284) and 5′AAAACTCCATACTACTCC 3′ (SEQ ID NO.: 1285). Primers were purchased from Operon Technologies (Alameda, Calif.).

[0075] A touchdown method was used for the first 14 cycles of amplification, starting at an annealing temperature of 68° C. and decreasing the annealing temperature 1° C. per cycle. Amplification was continued for an additional 30 cycles with an annealing temperature of 55° C. Denaturation and extension were carried out at 94° C. and 72° C., respectively. The product of this amplification was used as the template for a second set of PCR reactions. The products were de-salted (NAP column, Amersham Pharmacia Biotech) and precipitated with ethanol and sodium acetate prior to dissolving in hybridization buffer.

[0076] Array Hybridization

[0077] The hybridization mixture contained, 0.1-1 μM labeled analyte sample, 0.1-1 μM labeled reference sample, 1 μM Control Oligo 1 (SEQ ID NO.: 1286, 5′[Cy3] CTTGGCTGTCCCAGAATGCAAGAAGCCCAGACGGAAACCGTAGCTGCCCTGGTA GGTTTT), and 1 μM Control Oligo 2 (SEQ ID NO.: 1287, 5′[Cy3] TATATCAAAGCAGTAAGTAG) in 3M tetramethyl ammonium chloride, 0.05% Trition X-100,1 mM EDTA, 10 mM Tris HCl pH7.5. The sample was applied to the array surface under a 22×22 mm cover slip. Hybridization was carried out in a closed chamber containing a pool of hybridization buffer. The array with sample was heated to 95° C. for 20 minutes followed by warming at 60° C. for one hour. After hybridization, the array was washed three times with 6×SSPE (Sigma), 0.09% Tween, followed by three washes with 0.8×SSPE, 0.01% Tween at room temperature. After this wash, the array was dried centrifugally, stained with 2 μg/ml of CyS-Streptavidin (vendor) for 5 minutes at room temperature, washed with 6×SSPE, 0.09% Tween. Finally, the array was scanned using an Axon Genepix 3000 scanner to detect Cy3 and Cy5 fluorescence intensity. The signal intensity for each feature was determined using custom analysis software.

[0078] TA Cloning and Sequencing

[0079] The 190 base pair amplicon of sodium bisulfite treated DNA was cloned into plasmid pCR®2.1 using a TA cloning kit (Invitrogen, Carlsbad, Calif.) and manufacturer recommended protocols. Plasmid was isolated from 18 individual colonies, and the insert was sequenced. Sequencing was done on an ABI3100 sequencer with T7 and M13 primers using dye terminated DNA sequencing protocols.

[0080] Construction of 190 bp Duplex for Heterogeneous Methylation Study

[0081] A 190 base pair duplex with simulated methylation at position 25 was created. Oligonucleotides were obtained from Operon Technologies. The following oligonucleotides were obtained from Operon Technologies: Oligo A (SEQ ID NO.: 1288, 5′CCACCCTCTAATAACCAACCAACCCCTCCTCTTTCTTCCTCCAATACTAACAAA AAAACCCCCTCCAACCCTATCCCTCAAATCCTCTAA), Oligo B (SEQ ID NO.: 1289, 5′GTGTGTTTGGTGGTTGCGGAGAGGGGGAGAGTAGGTAGTGGGTGGTGGGGAGT AGTATGGAGTTGGTGGTGGGGAGTAGTATGGAGTTTT), Oligo C (SEQ ID NO.: 1290, 5′TTAGAGGATTTGAGGGATAGGGTTGGAGGGGGTTTTTTTGTTAGTATTGGAGG AAGAAAGAGGAGGGGTTGGTTGGTTATTAGAGGGTGGGGTGGATTGT), and Oligo D (SEQ ID NO.: 1291, 5′AAAACTCCATACTACTCCCCACCACCAACTCCATA CTACTCCCCACCACCCACTACCTACTCTCCCCCTCTCCGCAACCACCAAACACAC ACAATCCACC). Oligos A and B (70 pmoles each) were phosphorylated with polynucleotide kinase (New England BioLabs). The phosphorylated DNA was phenol extracted, chloroform extracted, then ethanol precipitated. Phosphorylated Oligo A was annealed with Oligo C, and phosphorylated Oligo B was annealed with Oligo D. The resulting duplexes were mixed in equimolar amounts and ligated with T4 ligase at 14° C. overnight. The resulting 190 base pair duplex was amplified as described above for the p16 promoter region.

[0082] Assay for Methylation by Hybridization to an Array of Oligonucleotide Probes

[0083] An example of one ore more essential features of the present invention is shown schematically in FIG. 6. For FIG. 6, oligonucleotide probes are covalently bound to a substrate. The central base of each probe for a given position is varied to test for the identity of the base by hybridization. The probe with which the most label is associated identifies the base at the central position. A cytosine at the probed position indicates methylation that prevented conversion by sodium bisulfite. A sample of genomic DNA is treated with sodium bisulfite under conditions that convert unmethylated cytosines to deoxyuridines. Methylated cytosines remain unconverted (FIG. 6A). At least one region of interest is amplified by PCR, which recapitulates the deoxyuracils in the template as thymidines. The product is labeled during amplification with an easily detectable tag such as a fluorophore. The presence of a cytosine or a thymidine at each position corresponding to a site of potential methylation is assayed by hybridization to a set of complementary oligonucleotide probes covalently bound to a substrate (FIG. 6B). Each probe for a given position is identical, except for a center base substitution used to determine the analyte sequence by hybridization. Many different CpG sites may be simultaneously queried with an array of many oligonucleotide probes.

[0084] A region of the promoter for the tumor suppressor gene p16 is tested using the method of the present invention. Hypermethylation of this promoter is known to repress transcription of p16 and is associated with a number of cancers. Samples of genomic DNA from lung tumor cell lines are treated with sodium bisulfite. In addition, a190 bp region of the p16 promoter is amplified and labeled. The sequence of the 190 base region of interest (prior to treatment with sodium bisulfite) is shown in FIG. 7 (GenBank accession number AL449423). After treatment with bisulfite, the strand shown was amplified and labeled. The region contains 36 cytosines. The numbers correspond to those are depicted in TABLE 2; 16 cytosines are within CpG dinucleotides (shaded) and 20 cytosines are not within CpG dinucleotides. The amplified DNA was analyzed by hybridization to an array of oligonucleotide probes, each 21 bases in length, synthesized directly on a glass surface by light-directed methods. Spatially patterned illumination for the photodeprotection step of the synthesis was accomplished using a digital micromirror device.

[0085] The result of hybridization and scanning of four probes designed to query a single cytosine (cytosine number 1) is shown in FIG. 8. The array was hybridized, washed, and scanned for fluorescence. Each 21 -nucleotide probe is complementary to the sequence surrounding cytosine number 1, with a different base for each probe in apposition to cytosine number 1. For example, the probe for A has a thymidine in that central position. The DNA analyzed with the Cy5 label was from a lung tumor cell line (H1299) in which all of the CpG dinucleotides in the 190-base analyzed region were previously found to be methylated (by using dye terminated sequencing of bisulfite treated DNA). The feature with the highest signal of the four features shown is the one probing for a cytosine (the variable base in the probe is a guanine). The ratio of the signal for this feature to the next highest signal (in the feature probing for a guanine) is 2.8, identifying the base in the analyte as a cytosine. A cytosine at this position was anticipated as the outcome of bisulfite treatment of the methylated base.

[0086] One comparison relevant to detection of methylation is between the signal in the feature that probes for a cytosine at each position and the signal in the feature that probes for a thymidine at the same position in the bisulfite treated DNA. The ratio of these signals (C:T) is listed for each of the cytosines in the analyzed sequence in TABLE 2. Cytosines outside of CpG dinucleotides that are not methylated serve as an internal indicator for the effectiveness of the bisulfite treatment in converting unmethylated cytosines to deoxyuracils and for the discrimination between cytosines and thymidines by the probes on the array. The ratio of signals in those features ranges from 0.24 to 1.09. Independent sequence analysis of the bisulfite-treated DNA confirmed complete conversion of all unmethylated cytosines to deoxyuracils. At the position queried by the probes shown in FIG. 8, the ratio of signals (C:T) is 3.57. The values range from 1.91 to 13.8 for cytosines in CpG dinucleotides (TABLE 2), in all cases considerably higher than the highest ratio of signals for the unmethylated cytosines. TABLE 2 Summary of Signal Intensity Ratios for Each Analyzed Cytosine H1299 & H69^(d) 25th C Duplex^(e) Cytosine C:T Ratio C:T Ratio Analyte(C:T)/ C:T Ratio C:T Ratio Analyte(C:T)/ Number^(g) Analyte^(a) Reference^(a) Ref(C:T)^(b) Score^(c) Analyte^(a) Reference^(a) Ref(C:T)^(b) Z Score^(c) 1 3.57 0.52 6.80 10.7 0.86 0.88 0.99 −0.90 2 0.46 0.54 0.85 −1.50 0.74 0.69 1.08 −0.29 3 0.44 0.36 1.23 −0.72 0.75 0.75 1.00 −0.82 4 0.39 0.29 1.34 −0.50 0.87 0.86 1.01 −0.76 5 13.8 0.39 35.7 69.7 0.90 0.89 1.01 −0.75 6 0.24 0.22 1.13 −0.94 1.07 0.96 1.12 −0.08 7 0.34 0.36 0.94 −1.33 1.01 0.99 1.01 −0.72 8 0.36 0.41 0.88 −1.45 0.70 0.58 1.22 0.58 9 0.33 0.27 1.23 −0.73 0.68 0.65 1.05 −0.50 10 9.28 0.41 22.5 42.8 0.82 0.68 1.20 0.46 11 0.93 0.53 1.76 0.36 0.85 0.88 0.97 −1.00 12 1.09 0.48 2.29 1.44 1.01 0.72 1.41 1.79 13 0.65 0.52 1.23 −0.69 0.85 0.76 1.11 −0.10 14 0.65 0.51 1.23 −0.60 0.83 0.80 1.05 −0.52 15 1.08 0.60 1.81 0.44 0.92 0.93 0.99 −0.87 16 3.55 0.54 6.64 10.3 0.94 0.72 1.30 1.12 17 0.27 0.11 2.44 1.75 0.62 0.56 1.11 −0.11 18 1.99 0.46 4.34 5.62 0.9 1.06 0.85 −1.76 19 2.36 0.60 3.91 4.75 1.10 0.76 1.45 2.08 20 1.91 0.53 3.63 4.18 1.01 0.82 1.23 0.68 21 0.40 0.18 2.27 1.39 0.51 0.45 1.14 0.08 22 3.11 0.69 4.54 6.05 0.82 0.71 1.16 0.24 23 3.38 0.59 5.73 8.46 1.07 0.68 1.56 2.77 24 0.45 0.27 1.68 0.20 0.60 0.49 1.22 0.62 25 3.55 0.52 6.81 10.7 1.48 0.62 2.38 7.97 26 0.62 0.29 2.11 1.07 0.81 0.75 1.08 −0.29 27 0.46 0.29 1.58 −0.01 0.7 0.74 0.94 −1.17 28 2.88 0.52 5.52 8.02 1.00 0.89 1.12 −0.04 29 2.11 0.43 4.85 6.66 0.93 0.58 1.59 2.95 30 3.40 0.42 8.09 13.3 1.01 0.62 1.67 3.47 31 0.70 0.38 1.87 0.57 0.77 0.58 1.32 1.23 32 0.60 0.34 1.75 0.33 0.79 0.50 1.57 2.82 33 0.37 0.18 2.04 0.93 0.57 0.50 1.14 0.09 34 2.14 0.52 4.10 5.13 0.82 0.63 1.30 1.09 35 2.11 0.44 4.77 6.51 1.21 0.72 1.69 3.55 36 4.48 0.49 9.15 15.5 1.18 0.80 1.47 2.20 20:80 Mixture^(f) Cytosine C:T Ratio C:T Ratio Analyte(C:T)/ Number^(g) Analyte^(a) Reference^(a) Ref(C:T)^(b) Z Score^(c) 1 0.99 0.52 1.92 4.61 2 0.70 0.70 1.00 1.01 3 0.39 0.32 1.20 1.80 4 0.44 0.36 1.22 1.88 5 1.16 0.49 2.35 6.29 6 0.32 0.64 0.5 −0.97 7 0.50 0.76 0.65 −0.37 8 0.36 0.62 0.58 −0.64 9 0.34 0.64 0.53 −0.85 10 1.43 0.67 2.15 5.51 11 0.62 0.90 0.69 −0.20 12 0.70 0.55 1.28 2.08 13 0.61 0.93 0.66 −0.35 14 0.51 0.68 0.74 −0.02 15 0.61 0.98 0.62 −0.48 16 1.90 0.86 2.21 5.71 17 0.20 0.51 0.39 −1.41 18 0.50 0.42 1.19 1.73 19 1.04 0.57 1.83 4.25 20 1.99 1.04 1.92 4.58 21 0.35 0.62 0.57 0.69 22 2.17 1.39 1.56 3.19 23 2.20 1.41 1.59 3.32 24 0.34 0.49 0.70 0.17 25 1.12 0.74 1.51 2.99 26 0.69 0.78 0.89 0.59 27 0.49 0.87 0.56 −0.73 28 1.24 0.63 1.98 4.82 29 0.93 0.96 0.96 0.85 30 0.91 1.11 0.82 0.29 31 0.59 0.73 0.81 0.25 32 0.53 0.67 0.80 0.21 33 0.30 0.59 0.51 −0.93 34 1.16 0.63 1.85 4.33 35 1.31 1.33 0.98 0.93 36 2.28 1.66 1.38 2.48

[0087] To provide an objective standard for discrimination between methylated and unmethylated cytosines and to facilitate visualization of changes in methylation state, a reference sequence containing a different label was co-hybridized with the array. DNA from a different lung tumor cell line (H69) in which the p16 promoter has been found to be unmethylated at each CpG in the 190 base region of interest was used a model reference sequence. Results were confirmed using dye terminated sequencing of bisulfite-treated DNA. The same 190 base region (FIG. 7) of H69 was amplified with a primer labeled with Cy3.

[0088] The result for cytosine number 1 is shown in FIGS. 8B and 8C. The probe for thymidine has the highest signal intensity, and the C:T ratio for the reference strand is 0.52 at this position. A useful method for judging changes in methylation state is to compare the C:T ratio for a set of probes with the analyte fluorophore to the C:T ratio for the same probes with the reference fluorophore. In FIG. 8 the ratio of sample fluorophore (Cy5) C:T ratio to reference fluorophore (Cy3) C:T ratio is 6.8. Using a ratio of ratios in this manner may, for example, reduce the effects of imperfect hybridization specificity on the results.

[0089] The ratio of ratios was computed for each cytosine in the original sequence and is listed in TABLE 2. Cytosines not part of a CpG were used as an internal standard for unmethylated positions. The ratios of signal ratios for these cytosines had a mean of 1.59 and a standard deviation of 0.49 (n=20) and were distributed normally. In the H1299 sample, the values for all 16 cytosines in CpGs were at least four standard deviations from the mean of values for cytosines not in CpGs (FIG. 9A; Z scores listed in TABLE 2). A study in which the dye labels were reversed between the analyte and reference samples yielded equivalent results.

[0090] Specificity for Detection of Heterogeneous Methylation

[0091] The example of the present invention shows that the region of the p16 promoter is uniformly methylated at all CpG sites in the H1299 cell line. For non-uniformity of methylation that may have important biological consequences (e.g., because methylation of all CpG sites within a promoter region does not have equal effect on transcription), the ability for the assay to independently discriminate methylation states at different CpG sites is essential.

[0092] The present invention may detect methylation at an individual site and define the threshold for assignment of methylation state. This may be shown, for example, by creating an 190 base pair test duplex (using chemical synthesis and ligation). One strand of the duplex is identical in sequence to bisulfite-treated H69 genomic DNA, except the position of the 25th cytosine simulates methylation by being a cytosine rather than a thymidine. The test duplex was labeled by amplification with a labeled primer, and bisulfite-treated DNA from H69 lung tumor cells was amplified and labeled for use as a reference sequence. Co-hybridization of the analyte and reference samples to the array resulted in the ratios of analyte(C:T) to reference(C:T) listed in TABLE 2 for all 36 cytosines.

[0093] The site of simulated methylation had an analyte(C:T):reference(C:T) ratio of 2.38, nearly eight standard deviations (Z score=7.97) from the mean of that ratio for the cytosines not in CpG dinucleotides (1.13±0.16,n=20). This ratio for the other cytosines in CpGs ranged from 0.91 to 1.64. These differed from the mean for the internal standard cytosines by −1.8 to 3.6 standard deviations (FIG. 9B and TABLE 2). Thus, the authentic cytosine could be clearly distinguished from the other potential positions of methylation by its considerably larger variation from the internal standards. The range of ratios for the positions simulating unmethylated CpGs suggests a threshold Z score of greater than 3.6 (i.e., greater than 3.6 standard deviations from the mean of the internal standards) to indicate a genuine difference from an unmethylated cytosine. In FIG. 9, the threshold for calling methylation is set to 3.6, indicated by the horizontal line at that value. In each case the reference sample was derived from unmethylated DNA.

[0094] Detection of Methylated DNA in the Presence of Unmethylated DNA

[0095] The present invention is able to detect methylated cytosines within analytes that contain a significant amount of DNA that is not methylated, a feature that may be particularly useful with biological samples of genomic DNA that include individual CpG sites that are partially but not exhaustively methylated.

[0096] The 190 base region shown in FIG. 7 was amplified separately from bisulfite-treated samples of genomic DNA from H1299 and H69. The amount of amplified DNA from each sample was estimated by visualization on an agarose gel, and the amplified samples were mixed in a ratio of approximately 20:80 (H1299:H69). This mixture approximates a sample in which 20% of each CpG is methylated. The mixture was labeled by an additional amplification with a labeled primer. A reference sample (derived purely from H69) was also amplified and labeled, and the analyte mixture and reference were co-hybridized to the methylation probe array.

[0097] The results of this hybridization are summarized in TABLE 2. Of the 16 cytosines in CpG dinucleotides, 8 had Z scores greater than 3.6, identifying them as partially methylated (FIG. 9C). The remaining 8 could not be distinguished from bases converted entirely to deoxyuracils by treatment with bisulfite.

[0098] The comparison to a sample of reference methylation state is especially useful, because information about differences in methylation state is important. Many comparisons may be used, such as, for example, comparing the difference between the analyte sample and a sample known to be unmethylated, comparing DNA from diseased tissue to a matched sample from healthy tissue or DNA from tissue at different points along a disease progression. In FIG. 8C, co-hybridization with a reference sample containing a different label facilitates visualization of changes in methylation state; the presence of two colors in one set of four probes may then be observed.

[0099] Other aspects of variability of the present invention may be assessed using the known unmethylated positions as internal standards (generally performed after the context-dependence of variability is accounted for). For example, a calculated Z score offers a measure of the statistical significance of the difference between the analyte to reference ratio of a given interrogated cytosine and those known to be unmethylated. The use of an empirically determined threshold Z score to judge methylation state is analogous to the use of an empirically determined threshold signal ratio to identify nucleotides in standard array-based sequence analysis. As used herein, the calculated Z score correlates with methylation state, and a single cytosine corresponding to a uniquely methylated position is distinguished from the unmethylated cytosines.

[0100] The present invention may detect methylation at an individual cytosine by hybridization to probes synthesized in situ using internal controls such as cytosines outside of CpG dinucleotides and a co-hybridized reference sample. The assay is designed to interrogate independent sites for methylation. With use of the present invention, additional probes may be included to interrogate other possible strands of DNA that reflect methylation status of a region. For example, after bisulfite treatment, the two strands of genomic DNA are no longer mutually complementary. Amplification of each produces two complementary strands of different sequence. Therefore, information about the methylation state of the initial sequence is contained in four different sequences of DNA, each of which can be analyzed independently on the same array.

[0101] With the present invention, as few as two array features can be used to effectively probe each cytosine in a region of interest. For example, using light directed methods of high feature density array synthesis, hundreds of thousands of features can be created on a single array to probe, in parallel, hundreds of thousands of potential methylation sites in widely dispersed regions of the genome. This method of array synthesis that allows for high feature densities and facile changes in probe content is particularly valuable for the de novo discovery of sites of aberrant methylation states.

[0102] Although the invention has been described in connection with specific embodiments, it should be understood that the invention as claimed should not be unduly limited to such specific embodiments. Modifications and variations of the described compositions and methods of the invention will be apparent to those skilled in the art without departing from the scope and spirit of the invention. Indeed, various modifications of the described compositions and modes of carrying out the invention that are obvious to those skilled in molecular biology or related arts are intended to be within the scope of the following claims.

1 1291 1 21 DNA Homo sapiens 1 aaccaaccaa taatctccca c 21 2 21 DNA Homo sapiens 2 accaaccaat tatctcccac c 21 3 21 DNA Homo sapiens 3 ccaaccaata ttctcccacc c 21 4 21 DNA Homo sapiens 4 caaccaataa tctcccaccc c 21 5 21 DNA Homo sapiens 5 aaccaataat ttcccacccc a 21 6 21 DNA Homo sapiens 6 accaataatc tcccacccca c 21 7 21 DNA Homo sapiens 7 ccaataatct tccaccccac c 21 8 21 DNA Homo sapiens 8 caataatctc tcaccccacc t 21 9 21 DNA Homo sapiens 9 aataatctcc taccccacct a 21 10 21 DNA Homo sapiens 10 ataatctccc tccccaccta a 21 11 21 DNA Homo sapiens 11 taatctccca tcccacctaa c 21 12 21 DNA Homo sapiens 12 aatctcccac tccacctaac t 21 13 21 DNA Homo sapiens 13 atctcccacc tcacctaact c 21 14 21 DNA Homo sapiens 14 tctcccaccc tacctaactc a 21 15 21 DNA Homo sapiens 15 ctcccacccc tcctaactca c 21 16 21 DNA Homo sapiens 16 tcccacccca tctaactcac a 21 17 21 DNA Homo sapiens 17 cccaccccac ttaactcaca c 21 18 21 DNA Homo sapiens 18 ccaccccacc taactcacac a 21 19 21 DNA Homo sapiens 19 caccccacct tactcacaca a 21 20 21 DNA Homo sapiens 20 accccaccta tctcacacaa a 21 21 21 DNA Homo sapiens 21 ccccacctaa ttcacacaaa c 21 22 21 DNA Homo sapiens 22 cccacctaac tcacacaaac c 21 23 21 DNA Homo sapiens 23 ccacctaact tacacaaacc a 21 24 21 DNA Homo sapiens 24 cacctaactc tcacaaacca c 21 25 21 DNA Homo sapiens 25 acctaactca tacaaaccac c 21 26 20 DNA Homo sapiens 26 atatagtttc gtcattcatc 20 27 20 DNA Homo sapiens 27 tacattgccc atgtaattaa 20 28 20 DNA Homo sapiens 28 atatagtttc gtcattcatc 20 29 20 DNA Homo sapiens 29 tacattgccc atgtaattaa 20 30 20 DNA Homo sapiens 30 agatagtttt gtcattcatc 20 31 20 DNA Homo sapiens 31 agatagtttc ttcattcatc 20 32 20 DNA Homo sapiens 32 agatagtttc gtcattcatc 20 33 20 DNA Homo sapiens 33 agatagtttc gttattcatc 20 34 21 DNA Homo sapiens 34 cctaactcac tcaaaccacc a 21 35 21 DNA Homo sapiens 35 ctaactcaca taaaccacca a 21 36 21 DNA Homo sapiens 36 taactcacac taaccaccaa c 21 37 21 DNA Homo sapiens 37 aaccaaccaa gaatctccca c 21 38 21 DNA Homo sapiens 38 accaaccaat gatctcccac c 21 39 21 DNA Homo sapiens 39 ccaaccaata gtctcccacc c 21 40 21 DNA Homo sapiens 40 caaccaataa gctcccaccc c 21 41 21 DNA Homo sapiens 41 aaccaataat gtcccacccc a 21 42 21 DNA Homo sapiens 42 accaataatc gcccacccca c 21 43 21 DNA Homo sapiens 43 ccaataatct gccaccccac c 21 44 21 DNA Homo sapiens 44 caataatctc gcaccccacc t 21 45 21 DNA Homo sapiens 45 aataatctcc gaccccacct a 21 46 21 DNA Homo sapiens 46 ataatctccc gccccaccta a 21 47 21 DNA Homo sapiens 47 taatctccca gcccacctaa c 21 48 21 DNA Homo sapiens 48 aatctcccac gccacctaac t 21 49 21 DNA Homo sapiens 49 atctcccacc gcacctaact c 21 50 21 DNA Homo sapiens 50 tctcccaccc gacctaactc a 21 51 21 DNA Homo sapiens 51 ctcccacccc gcctaactca c 21 52 21 DNA Homo sapiens 52 tcccacccca gctaactcac a 21 53 21 DNA Homo sapiens 53 cccaccccac gtaactcaca c 21 54 21 DNA Homo sapiens 54 ccaccccacc gaactcacac a 21 55 21 DNA Homo sapiens 55 caccccacct gactcacaca a 21 56 21 DNA Homo sapiens 56 accccaccta gctcacacaa a 21 57 21 DNA Homo sapiens 57 ccccacctaa gtcacacaaa c 21 58 21 DNA Homo sapiens 58 cccacctaac gcacacaaac c 21 59 21 DNA Homo sapiens 59 ccacctaact gacacaaacc a 21 60 21 DNA Homo sapiens 60 cacctaactc gcacaaacca c 21 61 21 DNA Homo sapiens 61 acctaactca gacaaaccac c 21 62 20 DNA Homo sapiens 62 tacattgccc atgtaattaa 20 63 20 DNA Homo sapiens 63 atatagtttc gtcattcatc 20 64 20 DNA Homo sapiens 64 tacattgccc atgtaattaa 20 65 20 DNA Homo sapiens 65 atatagtttc gtcattcatc 20 66 20 DNA Homo sapiens 66 agatagtttg gtcattcatc 20 67 20 DNA Homo sapiens 67 agatagtttc gtcattcatc 20 68 20 DNA Homo sapiens 68 agatagtttc ggcattcatc 20 69 20 DNA Homo sapiens 69 agatagtttc gtgattcatc 20 70 21 DNA Homo sapiens 70 cctaactcac gcaaaccacc a 21 71 21 DNA Homo sapiens 71 ctaactcaca gaaaccacca a 21 72 21 DNA Homo sapiens 72 taactcacac gaaccaccaa c 21 73 21 DNA Homo sapiens 73 aaccaaccaa caatctccca c 21 74 21 DNA Homo sapiens 74 accaaccaat catctcccac c 21 75 21 DNA Homo sapiens 75 ccaaccaata ctctcccacc c 21 76 21 DNA Homo sapiens 76 caaccaataa cctcccaccc c 21 77 21 DNA Homo sapiens 77 aaccaataat ctcccacccc a 21 78 21 DNA Homo sapiens 78 accaataatc ccccacccca c 21 79 21 DNA Homo sapiens 79 ccaataatct cccaccccac c 21 80 21 DNA Homo sapiens 80 caataatctc ccaccccacc t 21 81 21 DNA Homo sapiens 81 aataatctcc caccccacct a 21 82 21 DNA Homo sapiens 82 ataatctccc cccccaccta a 21 83 21 DNA Homo sapiens 83 taatctccca ccccacctaa c 21 84 21 DNA Homo sapiens 84 aatctcccac cccacctaac t 21 85 21 DNA Homo sapiens 85 atctcccacc ccacctaact c 21 86 21 DNA Homo sapiens 86 tctcccaccc cacctaactc a 21 87 21 DNA Homo sapiens 87 ctcccacccc ccctaactca c 21 88 21 DNA Homo sapiens 88 tcccacccca cctaactcac a 21 89 21 DNA Homo sapiens 89 cccaccccac ctaactcaca c 21 90 21 DNA Homo sapiens 90 ccaccccacc caactcacac a 21 91 21 DNA Homo sapiens 91 caccccacct cactcacaca a 21 92 21 DNA Homo sapiens 92 accccaccta cctcacacaa a 21 93 21 DNA Homo sapiens 93 ccccacctaa ctcacacaaa c 21 94 21 DNA Homo sapiens 94 cccacctaac ccacacaaac c 21 95 21 DNA Homo sapiens 95 ccacctaact cacacaaacc a 21 96 21 DNA Homo sapiens 96 cacctaactc ccacaaacca c 21 97 21 DNA Homo sapiens 97 acctaactca cacaaaccac c 21 98 20 DNA Homo sapiens 98 atatagtttc gtcattcatc 20 99 20 DNA Homo sapiens 99 tacattgccc atgtaattaa 20 100 20 DNA Homo sapiens 100 atatagtttc gtcattcatc 20 101 20 DNA Homo sapiens 101 tacattgccc atgtaattaa 20 102 20 DNA Homo sapiens 102 agatagtttc gtcattcatc 20 103 20 DNA Homo sapiens 103 agatagtttc ctcattcatc 20 104 20 DNA Homo sapiens 104 agatagtttc gccattcatc 20 105 20 DNA Homo sapiens 105 agatagtttc gtcattcatc 20 106 21 DNA Homo sapiens 106 cctaactcac ccaaaccacc a 21 107 21 DNA Homo sapiens 107 ctaactcaca caaaccacca a 21 108 21 DNA Homo sapiens 108 taactcacac caaccaccaa c 21 109 21 DNA Homo sapiens 109 aaccaaccaa aaatctccca c 21 110 21 DNA Homo sapiens 110 accaaccaat aatctcccac c 21 111 21 DNA Homo sapiens 111 ccaaccaata atctcccacc c 21 112 21 DNA Homo sapiens 112 caaccaataa actcccaccc c 21 113 21 DNA Homo sapiens 113 aaccaataat atcccacccc a 21 114 21 DNA Homo sapiens 114 accaataatc acccacccca c 21 115 21 DNA Homo sapiens 115 ccaataatct accaccccac c 21 116 21 DNA Homo sapiens 116 caataatctc acaccccacc t 21 117 21 DNA Homo sapiens 117 aataatctcc aaccccacct a 21 118 21 DNA Homo sapiens 118 ataatctccc accccaccta a 21 119 21 DNA Homo sapiens 119 taatctccca acccacctaa c 21 120 21 DNA Homo sapiens 120 aatctcccac accacctaac t 21 121 21 DNA Homo sapiens 121 atctcccacc acacctaact c 21 122 21 DNA Homo sapiens 122 tctcccaccc aacctaactc a 21 123 21 DNA Homo sapiens 123 ctcccacccc acctaactca c 21 124 21 DNA Homo sapiens 124 tcccacccca actaactcac a 21 125 21 DNA Homo sapiens 125 cccaccccac ataactcaca c 21 126 21 DNA Homo sapiens 126 ccaccccacc aaactcacac a 21 127 21 DNA Homo sapiens 127 caccccacct aactcacaca a 21 128 21 DNA Homo sapiens 128 accccaccta actcacacaa a 21 129 21 DNA Homo sapiens 129 ccccacctaa atcacacaaa c 21 130 21 DNA Homo sapiens 130 cccacctaac acacacaaac c 21 131 21 DNA Homo sapiens 131 ccacctaact aacacaaacc a 21 132 21 DNA Homo sapiens 132 cacctaactc acacaaacca c 21 133 21 DNA Homo sapiens 133 acctaactca aacaaaccac c 21 134 20 DNA Homo sapiens 134 tacattgccc atgtaattaa 20 135 20 DNA Homo sapiens 135 atatagtttc gtcattcatc 20 136 20 DNA Homo sapiens 136 tacattgccc atgtaattaa 20 137 20 DNA Homo sapiens 137 atatagtttc gtcattcatc 20 138 20 DNA Homo sapiens 138 agatagttta gtcattcatc 20 139 20 DNA Homo sapiens 139 agatagtttc atcattcatc 20 140 20 DNA Homo sapiens 140 agatagtttc gacattcatc 20 141 20 DNA Homo sapiens 141 agatagtttc gtaattcatc 20 142 21 DNA Homo sapiens 142 cctaactcac acaaaccacc a 21 143 21 DNA Homo sapiens 143 ctaactcaca aaaaccacca a 21 144 21 DNA Homo sapiens 144 taactcacac aaaccaccaa c 21 145 21 DNA Homo sapiens 145 aactcacaca taccaccaac a 21 146 21 DNA Homo sapiens 146 actcacacaa tccaccaaca c 21 147 21 DNA Homo sapiens 147 ctcacacaaa tcaccaacac c 21 148 21 DNA Homo sapiens 148 tcacacaaac taccaacacc t 21 149 21 DNA Homo sapiens 149 cacacaaacc tccaacacct c 21 150 21 DNA Homo sapiens 150 acacaaacca tcaacacctc t 21 151 21 DNA Homo sapiens 151 cacaaaccac taacacctct c 21 152 21 DNA Homo sapiens 152 acaaaccacc tacacctctc c 21 153 21 DNA Homo sapiens 153 caaaccacca tcacctctcc c 21 154 21 DNA Homo sapiens 154 aaaccaccaa tacctctccc c 21 155 21 DNA Homo sapiens 155 aaccaccaac tcctctcccc c 21 156 21 DNA Homo sapiens 156 accaccaaca tctctccccc t 21 157 21 DNA Homo sapiens 157 ccaccaacac ttctccccct c 21 158 21 DNA Homo sapiens 158 caccaacacc tctccccctc t 21 159 21 DNA Homo sapiens 159 accaacacct ttccccctct c 21 160 21 DNA Homo sapiens 160 ccaacacctc tccccctctc a 21 161 21 DNA Homo sapiens 161 caacacctct tcccctctca t 21 162 21 DNA Homo sapiens 162 aacacctctc tccctctcat c 21 163 21 DNA Homo sapiens 163 acacctctcc tcctctcatc c 21 164 21 DNA Homo sapiens 164 cacctctccc tctctcatcc a 21 165 21 DNA Homo sapiens 165 acctctcccc ttctcatcca t 21 166 21 DNA Homo sapiens 166 cctctccccc tctcatccat c 21 167 20 DNA Homo sapiens 167 atatagtttc gtcattcatc 20 168 20 DNA Homo sapiens 168 tacattgccc atgtaattaa 20 169 20 DNA Homo sapiens 169 atatagtttc gtcattcatc 20 170 20 DNA Homo sapiens 170 tacattgccc atgtaattaa 20 171 20 DNA Homo sapiens 171 agatagtttt gtcattcatc 20 172 20 DNA Homo sapiens 172 agatagtttc ttcattcatc 20 173 20 DNA Homo sapiens 173 agatagtttc gtcattcatc 20 174 20 DNA Homo sapiens 174 agatagtttc gttattcatc 20 175 21 DNA Homo sapiens 175 ctctccccct ttcatccatc a 21 176 21 DNA Homo sapiens 176 tctccccctc tcatccatca c 21 177 21 DNA Homo sapiens 177 ctccccctct tatccatcac c 21 178 21 DNA Homo sapiens 178 tccccctctc ttccatcacc c 21 179 21 DNA Homo sapiens 179 ccccctctca tccatcaccc a 21 180 21 DNA Homo sapiens 180 cccctctcat tcatcaccca c 21 181 21 DNA Homo sapiens 181 aactcacaca gaccaccaac a 21 182 21 DNA Homo sapiens 182 actcacacaa gccaccaaca c 21 183 21 DNA Homo sapiens 183 ctcacacaaa gcaccaacac c 21 184 21 DNA Homo sapiens 184 tcacacaaac gaccaacacc t 21 185 21 DNA Homo sapiens 185 cacacaaacc gccaacacct c 21 186 21 DNA Homo sapiens 186 acacaaacca gcaacacctc t 21 187 21 DNA Homo sapiens 187 cacaaaccac gaacacctct c 21 188 21 DNA Homo sapiens 188 acaaaccacc gacacctctc c 21 189 21 DNA Homo sapiens 189 caaaccacca gcacctctcc c 21 190 21 DNA Homo sapiens 190 aaaccaccaa gacctctccc c 21 191 21 DNA Homo sapiens 191 aaccaccaac gcctctcccc c 21 192 21 DNA Homo sapiens 192 accaccaaca gctctccccc t 21 193 21 DNA Homo sapiens 193 ccaccaacac gtctccccct c 21 194 21 DNA Homo sapiens 194 caccaacacc gctccccctc t 21 195 21 DNA Homo sapiens 195 accaacacct gtccccctct c 21 196 21 DNA Homo sapiens 196 ccaacacctc gccccctctc a 21 197 21 DNA Homo sapiens 197 caacacctct gcccctctca t 21 198 21 DNA Homo sapiens 198 aacacctctc gccctctcat c 21 199 21 DNA Homo sapiens 199 acacctctcc gcctctcatc c 21 200 21 DNA Homo sapiens 200 cacctctccc gctctcatcc a 21 201 21 DNA Homo sapiens 201 acctctcccc gtctcatcca t 21 202 21 DNA Homo sapiens 202 cctctccccc gctcatccat c 21 203 20 DNA Homo sapiens 203 tacattgccc atgtaattaa 20 204 20 DNA Homo sapiens 204 atatagtttc gtcattcatc 20 205 20 DNA Homo sapiens 205 tacattgccc atgtaattaa 20 206 20 DNA Homo sapiens 206 atatagtttc gtcattcatc 20 207 20 DNA Homo sapiens 207 agatagtttg gtcattcatc 20 208 20 DNA Homo sapiens 208 agatagtttc gtcattcatc 20 209 20 DNA Homo sapiens 209 agatagtttc ggcattcatc 20 210 20 DNA Homo sapiens 210 agatagtttc gtgattcatc 20 211 21 DNA Homo sapiens 211 ctctccccct gtcatccatc a 21 212 21 DNA Homo sapiens 212 tctccccctc gcatccatca c 21 213 21 DNA Homo sapiens 213 ctccccctct gatccatcac c 21 214 21 DNA Homo sapiens 214 tccccctctc gtccatcacc c 21 215 21 DNA Homo sapiens 215 ccccctctca gccatcaccc a 21 216 21 DNA Homo sapiens 216 cccctctcat gcatcaccca c 21 217 21 DNA Homo sapiens 217 aactcacaca caccaccaac a 21 218 21 DNA Homo sapiens 218 actcacacaa cccaccaaca c 21 219 21 DNA Homo sapiens 219 ctcacacaaa ccaccaacac c 21 220 21 DNA Homo sapiens 220 tcacacaaac caccaacacc t 21 221 21 DNA Homo sapiens 221 cacacaaacc cccaacacct c 21 222 21 DNA Homo sapiens 222 acacaaacca ccaacacctc t 21 223 21 DNA Homo sapiens 223 cacaaaccac caacacctct c 21 224 21 DNA Homo sapiens 224 acaaaccacc cacacctctc c 21 225 21 DNA Homo sapiens 225 caaaccacca ccacctctcc c 21 226 21 DNA Homo sapiens 226 aaaccaccaa cacctctccc c 21 227 21 DNA Homo sapiens 227 aaccaccaac ccctctcccc c 21 228 21 DNA Homo sapiens 228 accaccaaca cctctccccc t 21 229 21 DNA Homo sapiens 229 ccaccaacac ctctccccct c 21 230 21 DNA Homo sapiens 230 caccaacacc cctccccctc t 21 231 21 DNA Homo sapiens 231 accaacacct ctccccctct c 21 232 21 DNA Homo sapiens 232 ccaacacctc cccccctctc a 21 233 21 DNA Homo sapiens 233 caacacctct ccccctctca t 21 234 21 DNA Homo sapiens 234 aacacctctc cccctctcat c 21 235 21 DNA Homo sapiens 235 acacctctcc ccctctcatc c 21 236 21 DNA Homo sapiens 236 cacctctccc cctctcatcc a 21 237 21 DNA Homo sapiens 237 acctctcccc ctctcatcca t 21 238 21 DNA Homo sapiens 238 cctctccccc cctcatccat c 21 239 20 DNA Homo sapiens 239 atatagtttc gtcattcatc 20 240 20 DNA Homo sapiens 240 tacattgccc atgtaattaa 20 241 20 DNA Homo sapiens 241 atatagtttc gtcattcatc 20 242 20 DNA Homo sapiens 242 tacattgccc atgtaattaa 20 243 20 DNA Homo sapiens 243 agatagtttc gtcattcatc 20 244 20 DNA Homo sapiens 244 agatagtttc ctcattcatc 20 245 20 DNA Homo sapiens 245 agatagtttc gccattcatc 20 246 20 DNA Homo sapiens 246 agatagtttc gtcattcatc 20 247 21 DNA Homo sapiens 247 ctctccccct ctcatccatc a 21 248 21 DNA Homo sapiens 248 tctccccctc ccatccatca c 21 249 21 DNA Homo sapiens 249 ctccccctct catccatcac c 21 250 21 DNA Homo sapiens 250 tccccctctc ctccatcacc c 21 251 21 DNA Homo sapiens 251 ccccctctca cccatcaccc a 21 252 21 DNA Homo sapiens 252 cccctctcat ccatcaccca c 21 253 21 DNA Homo sapiens 253 aactcacaca aaccaccaac a 21 254 21 DNA Homo sapiens 254 actcacacaa accaccaaca c 21 255 21 DNA Homo sapiens 255 ctcacacaaa acaccaacac c 21 256 21 DNA Homo sapiens 256 tcacacaaac aaccaacacc t 21 257 21 DNA Homo sapiens 257 cacacaaacc accaacacct c 21 258 21 DNA Homo sapiens 258 acacaaacca acaacacctc t 21 259 21 DNA Homo sapiens 259 cacaaaccac aaacacctct c 21 260 21 DNA Homo sapiens 260 acaaaccacc aacacctctc c 21 261 21 DNA Homo sapiens 261 caaaccacca acacctctcc c 21 262 21 DNA Homo sapiens 262 aaaccaccaa aacctctccc c 21 263 21 DNA Homo sapiens 263 aaccaccaac acctctcccc c 21 264 21 DNA Homo sapiens 264 accaccaaca actctccccc t 21 265 21 DNA Homo sapiens 265 ccaccaacac atctccccct c 21 266 21 DNA Homo sapiens 266 caccaacacc actccccctc t 21 267 21 DNA Homo sapiens 267 accaacacct atccccctct c 21 268 21 DNA Homo sapiens 268 ccaacacctc accccctctc a 21 269 21 DNA Homo sapiens 269 caacacctct acccctctca t 21 270 21 DNA Homo sapiens 270 aacacctctc accctctcat c 21 271 21 DNA Homo sapiens 271 acacctctcc acctctcatc c 21 272 21 DNA Homo sapiens 272 cacctctccc actctcatcc a 21 273 21 DNA Homo sapiens 273 acctctcccc atctcatcca t 21 274 21 DNA Homo sapiens 274 cctctccccc actcatccat c 21 275 20 DNA Homo sapiens 275 tacattgccc atgtaattaa 20 276 20 DNA Homo sapiens 276 atatagtttc gtcattcatc 20 277 20 DNA Homo sapiens 277 tacattgccc atgtaattaa 20 278 20 DNA Homo sapiens 278 atatagtttc gtcattcatc 20 279 20 DNA Homo sapiens 279 agatagttta gtcattcatc 20 280 20 DNA Homo sapiens 280 agatagtttc atcattcatc 20 281 20 DNA Homo sapiens 281 agatagtttc gacattcatc 20 282 20 DNA Homo sapiens 282 agatagtttc gtaattcatc 20 283 21 DNA Homo sapiens 283 ctctccccct atcatccatc a 21 284 21 DNA Homo sapiens 284 tctccccctc acatccatca c 21 285 21 DNA Homo sapiens 285 ctccccctct aatccatcac c 21 286 21 DNA Homo sapiens 286 tccccctctc atccatcacc c 21 287 21 DNA Homo sapiens 287 ccccctctca accatcaccc a 21 288 21 DNA Homo sapiens 288 cccctctcat acatcaccca c 21 289 21 DNA Homo sapiens 289 ccctctcatc tatcacccac c 21 290 21 DNA Homo sapiens 290 cctctcatcc ttcacccacc a 21 291 21 DNA Homo sapiens 291 ctctcatcca tcacccacca c 21 292 21 DNA Homo sapiens 292 tctcatccat tacccaccac c 21 293 21 DNA Homo sapiens 293 ctcatccatc tcccaccacc c 21 294 21 DNA Homo sapiens 294 tcatccatca tccaccaccc c 21 295 21 DNA Homo sapiens 295 catccatcac tcaccacccc t 21 296 21 DNA Homo sapiens 296 atccatcacc taccacccct c 21 297 21 DNA Homo sapiens 297 tccatcaccc tccacccctc a 21 298 21 DNA Homo sapiens 298 ccatcaccca tcacccctca t 21 299 21 DNA Homo sapiens 299 catcacccac tacccctcat c 21 300 21 DNA Homo sapiens 300 atcacccacc tcccctcatc a 21 301 21 DNA Homo sapiens 301 tcacccacca tccctcatca t 21 302 21 DNA Homo sapiens 302 cacccaccac tcctcatcat a 21 303 21 DNA Homo sapiens 303 acccaccacc tctcatcata c 21 304 21 DNA Homo sapiens 304 cccaccaccc ttcatcatac c 21 305 21 DNA Homo sapiens 305 ccaccacccc tcatcatacc t 21 306 21 DNA Homo sapiens 306 caccacccct tatcatacct c 21 307 21 DNA Homo sapiens 307 accacccctc ttcatacctc a 21 308 20 DNA Homo sapiens 308 atatagtttc gtcattcatc 20 309 20 DNA Homo sapiens 309 tacattgccc atgtaattaa 20 310 20 DNA Homo sapiens 310 atatagtttc gtcattcatc 20 311 20 DNA Homo sapiens 311 tacattgccc atgtaattaa 20 312 20 DNA Homo sapiens 312 agatagtttt gtcattcatc 20 313 20 DNA Homo sapiens 313 agatagtttc ttcattcatc 20 314 20 DNA Homo sapiens 314 agatagtttc gtcattcatc 20 315 20 DNA Homo sapiens 315 agatagtttc gttattcatc 20 316 21 DNA Homo sapiens 316 ccacccctca tcatacctca a 21 317 21 DNA Homo sapiens 317 cacccctcat tatacctcaa c 21 318 21 DNA Homo sapiens 318 acccctcatc ttacctcaac c 21 319 21 DNA Homo sapiens 319 cccctcatca tacctcaacc a 21 320 21 DNA Homo sapiens 320 ccctcatcat tcctcaacca c 21 321 21 DNA Homo sapiens 321 cctcatcata tctcaaccac c 21 322 21 DNA Homo sapiens 322 ctcatcatac ttcaaccacc a 21 323 21 DNA Homo sapiens 323 tcatcatacc tcaaccacca c 21 324 21 DNA Homo sapiens 324 catcatacct taaccaccac c 21 325 21 DNA Homo sapiens 325 ccctctcatc gatcacccac c 21 326 21 DNA Homo sapiens 326 cctctcatcc gtcacccacc a 21 327 21 DNA Homo sapiens 327 ctctcatcca gcacccacca c 21 328 21 DNA Homo sapiens 328 tctcatccat gacccaccac c 21 329 21 DNA Homo sapiens 329 ctcatccatc gcccaccacc c 21 330 21 DNA Homo sapiens 330 tcatccatca gccaccaccc c 21 331 21 DNA Homo sapiens 331 catccatcac gcaccacccc t 21 332 21 DNA Homo sapiens 332 atccatcacc gaccacccct c 21 333 21 DNA Homo sapiens 333 tccatcaccc gccacccctc a 21 334 21 DNA Homo sapiens 334 ccatcaccca gcacccctca t 21 335 21 DNA Homo sapiens 335 catcacccac gacccctcat c 21 336 21 DNA Homo sapiens 336 atcacccacc gcccctcatc a 21 337 21 DNA Homo sapiens 337 tcacccacca gccctcatca t 21 338 21 DNA Homo sapiens 338 cacccaccac gcctcatcat a 21 339 21 DNA Homo sapiens 339 acccaccacc gctcatcata c 21 340 21 DNA Homo sapiens 340 cccaccaccc gtcatcatac c 21 341 21 DNA Homo sapiens 341 ccaccacccc gcatcatacc t 21 342 21 DNA Homo sapiens 342 caccacccct gatcatacct c 21 343 21 DNA Homo sapiens 343 accacccctc gtcatacctc a 21 344 20 DNA Homo sapiens 344 tacattgccc atgtaattaa 20 345 20 DNA Homo sapiens 345 atatagtttc gtcattcatc 20 346 20 DNA Homo sapiens 346 tacattgccc atgtaattaa 20 347 20 DNA Homo sapiens 347 atatagtttc gtcattcatc 20 348 20 DNA Homo sapiens 348 agatagtttg gtcattcatc 20 349 20 DNA Homo sapiens 349 agatagtttc gtcattcatc 20 350 20 DNA Homo sapiens 350 agatagtttc ggcattcatc 20 351 20 DNA Homo sapiens 351 agatagtttc gtgattcatc 20 352 21 DNA Homo sapiens 352 ccacccctca gcatacctca a 21 353 21 DNA Homo sapiens 353 cacccctcat gatacctcaa c 21 354 21 DNA Homo sapiens 354 acccctcatc gtacctcaac c 21 355 21 DNA Homo sapiens 355 cccctcatca gacctcaacc a 21 356 21 DNA Homo sapiens 356 ccctcatcat gcctcaacca c 21 357 21 DNA Homo sapiens 357 cctcatcata gctcaaccac c 21 358 21 DNA Homo sapiens 358 ctcatcatac gtcaaccacc a 21 359 21 DNA Homo sapiens 359 tcatcatacc gcaaccacca c 21 360 21 DNA Homo sapiens 360 catcatacct gaaccaccac c 21 361 21 DNA Homo sapiens 361 ccctctcatc catcacccac c 21 362 21 DNA Homo sapiens 362 cctctcatcc ctcacccacc a 21 363 21 DNA Homo sapiens 363 ctctcatcca ccacccacca c 21 364 21 DNA Homo sapiens 364 tctcatccat cacccaccac c 21 365 21 DNA Homo sapiens 365 ctcatccatc ccccaccacc c 21 366 21 DNA Homo sapiens 366 tcatccatca cccaccaccc c 21 367 21 DNA Homo sapiens 367 catccatcac ccaccacccc t 21 368 21 DNA Homo sapiens 368 atccatcacc caccacccct c 21 369 21 DNA Homo sapiens 369 tccatcaccc cccacccctc a 21 370 21 DNA Homo sapiens 370 ccatcaccca ccacccctca t 21 371 21 DNA Homo sapiens 371 catcacccac cacccctcat c 21 372 21 DNA Homo sapiens 372 atcacccacc ccccctcatc a 21 373 21 DNA Homo sapiens 373 tcacccacca cccctcatca t 21 374 21 DNA Homo sapiens 374 cacccaccac ccctcatcat a 21 375 21 DNA Homo sapiens 375 acccaccacc cctcatcata c 21 376 21 DNA Homo sapiens 376 cccaccaccc ctcatcatac c 21 377 21 DNA Homo sapiens 377 ccaccacccc ccatcatacc t 21 378 21 DNA Homo sapiens 378 caccacccct catcatacct c 21 379 21 DNA Homo sapiens 379 accacccctc ctcatacctc a 21 380 20 DNA Homo sapiens 380 atatagtttc gtcattcatc 20 381 20 DNA Homo sapiens 381 tacattgccc atgtaattaa 20 382 20 DNA Homo sapiens 382 atatagtttc gtcattcatc 20 383 20 DNA Homo sapiens 383 tacattgccc atgtaattaa 20 384 20 DNA Homo sapiens 384 agatagtttc gtcattcatc 20 385 20 DNA Homo sapiens 385 agatagtttc ctcattcatc 20 386 20 DNA Homo sapiens 386 agatagtttc gccattcatc 20 387 20 DNA Homo sapiens 387 agatagtttc gtcattcatc 20 388 21 DNA Homo sapiens 388 ccacccctca ccatacctca a 21 389 21 DNA Homo sapiens 389 cacccctcat catacctcaa c 21 390 21 DNA Homo sapiens 390 acccctcatc ctacctcaac c 21 391 21 DNA Homo sapiens 391 cccctcatca cacctcaacc a 21 392 21 DNA Homo sapiens 392 ccctcatcat ccctcaacca c 21 393 21 DNA Homo sapiens 393 cctcatcata cctcaaccac c 21 394 21 DNA Homo sapiens 394 ctcatcatac ctcaaccacc a 21 395 21 DNA Homo sapiens 395 tcatcatacc ccaaccacca c 21 396 21 DNA Homo sapiens 396 catcatacct caaccaccac c 21 397 21 DNA Homo sapiens 397 ccctctcatc aatcacccac c 21 398 21 DNA Homo sapiens 398 cctctcatcc atcacccacc a 21 399 21 DNA Homo sapiens 399 ctctcatcca acacccacca c 21 400 21 DNA Homo sapiens 400 tctcatccat aacccaccac c 21 401 21 DNA Homo sapiens 401 ctcatccatc acccaccacc c 21 402 21 DNA Homo sapiens 402 tcatccatca accaccaccc c 21 403 21 DNA Homo sapiens 403 catccatcac acaccacccc t 21 404 21 DNA Homo sapiens 404 atccatcacc aaccacccct c 21 405 21 DNA Homo sapiens 405 tccatcaccc accacccctc a 21 406 21 DNA Homo sapiens 406 ccatcaccca acacccctca t 21 407 21 DNA Homo sapiens 407 catcacccac aacccctcat c 21 408 21 DNA Homo sapiens 408 atcacccacc acccctcatc a 21 409 21 DNA Homo sapiens 409 tcacccacca accctcatca t 21 410 21 DNA Homo sapiens 410 cacccaccac acctcatcat a 21 411 21 DNA Homo sapiens 411 acccaccacc actcatcata c 21 412 21 DNA Homo sapiens 412 cccaccaccc atcatcatac c 21 413 21 DNA Homo sapiens 413 ccaccacccc acatcatacc t 21 414 21 DNA Homo sapiens 414 caccacccct aatcatacct c 21 415 21 DNA Homo sapiens 415 accacccctc atcatacctc a 21 416 20 DNA Homo sapiens 416 tacattgccc atgtaattaa 20 417 20 DNA Homo sapiens 417 atatagtttc gtcattcatc 20 418 20 DNA Homo sapiens 418 tacattgccc atgtaattaa 20 419 20 DNA Homo sapiens 419 atatagtttc gtcattcatc 20 420 20 DNA Homo sapiens 420 agatagttta gtcattcatc 20 421 20 DNA Homo sapiens 421 agatagtttc atcattcatc 20 422 20 DNA Homo sapiens 422 agatagtttc gacattcatc 20 423 20 DNA Homo sapiens 423 agatagtttc gtaattcatc 20 424 21 DNA Homo sapiens 424 ccacccctca acatacctca a 21 425 21 DNA Homo sapiens 425 cacccctcat aatacctcaa c 21 426 21 DNA Homo sapiens 426 acccctcatc atacctcaac c 21 427 21 DNA Homo sapiens 427 cccctcatca aacctcaacc a 21 428 21 DNA Homo sapiens 428 ccctcatcat acctcaacca c 21 429 21 DNA Homo sapiens 429 cctcatcata actcaaccac c 21 430 21 DNA Homo sapiens 430 ctcatcatac atcaaccacc a 21 431 21 DNA Homo sapiens 431 tcatcatacc acaaccacca c 21 432 21 DNA Homo sapiens 432 catcatacct aaaccaccac c 21 433 21 DNA Homo sapiens 433 atcatacctc taccaccacc c 21 434 21 DNA Homo sapiens 434 tcatacctca tccaccaccc c 21 435 21 DNA Homo sapiens 435 catacctcaa tcaccacccc t 21 436 21 DNA Homo sapiens 436 atacctcaac taccacccct c 21 437 21 DNA Homo sapiens 437 tacctcaacc tccacccctc a 21 438 21 DNA Homo sapiens 438 acctcaacca tcacccctca t 21 439 21 DNA Homo sapiens 439 cctcaaccac tacccctcat c 21 440 21 DNA Homo sapiens 440 ctcaaccacc tcccctcatc a 21 441 21 DNA Homo sapiens 441 tcaaccacca tccctcatca t 21 442 21 DNA Homo sapiens 442 caaccaccac tcctcatcat a 21 443 21 DNA Homo sapiens 443 aaccaccacc tctcatcata c 21 444 21 DNA Homo sapiens 444 accaccaccc ttcatcatac c 21 445 21 DNA Homo sapiens 445 ccaccacccc tcatcatacc t 21 446 21 DNA Homo sapiens 446 caccacccct tatcatacct c 21 447 21 DNA Homo sapiens 447 accacccctc ttcatacctc a 21 448 21 DNA Homo sapiens 448 ccacccctca tcatacctca a 21 449 20 DNA Homo sapiens 449 atatagtttc gtcattcatc 20 450 20 DNA Homo sapiens 450 tacattgccc atgtaattaa 20 451 20 DNA Homo sapiens 451 atatagtttc gtcattcatc 20 452 20 DNA Homo sapiens 452 tacattgccc atgtaattaa 20 453 20 DNA Homo sapiens 453 agatagtttt gtcattcatc 20 454 20 DNA Homo sapiens 454 agatagtttc ttcattcatc 20 455 20 DNA Homo sapiens 455 agatagtttc gtcattcatc 20 456 20 DNA Homo sapiens 456 agatagtttc gttattcatc 20 457 21 DNA Homo sapiens 457 cacccctcat tatacctcaa a 21 458 21 DNA Homo sapiens 458 acccctcatc ttacctcaaa a 21 459 21 DNA Homo sapiens 459 cccctcatca tacctcaaaa a 21 460 21 DNA Homo sapiens 460 ccctcatcat tcctcaaaaa c 21 461 21 DNA Homo sapiens 461 cctcatcata tctcaaaaac c 21 462 21 DNA Homo sapiens 462 ctcatcatac ttcaaaaacc a 21 463 21 DNA Homo sapiens 463 tcatcatacc tcaaaaacca a 21 464 21 DNA Homo sapiens 464 catcatacct taaaaaccaa c 21 465 21 DNA Homo sapiens 465 atcatacctc taaaaccaac t 21 466 21 DNA Homo sapiens 466 tcatacctca taaaccaact a 21 467 21 DNA Homo sapiens 467 catacctcaa taaccaacta a 21 468 21 DNA Homo sapiens 468 atacctcaaa taccaactaa c 21 469 21 DNA Homo sapiens 469 atcatacctc gaccaccacc c 21 470 21 DNA Homo sapiens 470 tcatacctca gccaccaccc c 21 471 21 DNA Homo sapiens 471 catacctcaa gcaccacccc t 21 472 21 DNA Homo sapiens 472 atacctcaac gaccacccct c 21 473 21 DNA Homo sapiens 473 tacctcaacc gccacccctc a 21 474 21 DNA Homo sapiens 474 acctcaacca gcacccctca t 21 475 21 DNA Homo sapiens 475 cctcaaccac gacccctcat c 21 476 21 DNA Homo sapiens 476 ctcaaccacc gcccctcatc a 21 477 21 DNA Homo sapiens 477 tcaaccacca gccctcatca t 21 478 21 DNA Homo sapiens 478 caaccaccac gcctcatcat a 21 479 21 DNA Homo sapiens 479 aaccaccacc gctcatcata c 21 480 21 DNA Homo sapiens 480 accaccaccc gtcatcatac c 21 481 21 DNA Homo sapiens 481 ccaccacccc gcatcatacc t 21 482 21 DNA Homo sapiens 482 caccacccct gatcatacct c 21 483 21 DNA Homo sapiens 483 accacccctc gtcatacctc a 21 484 21 DNA Homo sapiens 484 ccacccctca gcatacctca a 21 485 20 DNA Homo sapiens 485 tacattgccc atgtaattaa 20 486 20 DNA Homo sapiens 486 atatagtttc gtcattcatc 20 487 20 DNA Homo sapiens 487 tacattgccc atgtaattaa 20 488 20 DNA Homo sapiens 488 atatagtttc gtcattcatc 20 489 20 DNA Homo sapiens 489 agatagtttg gtcattcatc 20 490 20 DNA Homo sapiens 490 agatagtttc gtcattcatc 20 491 20 DNA Homo sapiens 491 agatagtttc ggcattcatc 20 492 20 DNA Homo sapiens 492 agatagtttc gtgattcatc 20 493 21 DNA Homo sapiens 493 cacccctcat gatacctcaa a 21 494 21 DNA Homo sapiens 494 acccctcatc gtacctcaaa a 21 495 21 DNA Homo sapiens 495 cccctcatca gacctcaaaa a 21 496 21 DNA Homo sapiens 496 ccctcatcat gcctcaaaaa c 21 497 21 DNA Homo sapiens 497 cctcatcata gctcaaaaac c 21 498 21 DNA Homo sapiens 498 ctcatcatac gtcaaaaacc a 21 499 21 DNA Homo sapiens 499 tcatcatacc gcaaaaacca a 21 500 21 DNA Homo sapiens 500 catcatacct gaaaaaccaa c 21 501 21 DNA Homo sapiens 501 atcatacctc gaaaaccaac t 21 502 21 DNA Homo sapiens 502 tcatacctca gaaaccaact a 21 503 21 DNA Homo sapiens 503 catacctcaa gaaccaacta a 21 504 21 DNA Homo sapiens 504 atacctcaaa gaccaactaa c 21 505 21 DNA Homo sapiens 505 atcatacctc caccaccacc c 21 506 21 DNA Homo sapiens 506 tcatacctca cccaccaccc c 21 507 21 DNA Homo sapiens 507 catacctcaa ccaccacccc t 21 508 21 DNA Homo sapiens 508 atacctcaac caccacccct c 21 509 21 DNA Homo sapiens 509 tacctcaacc cccacccctc a 21 510 21 DNA Homo sapiens 510 acctcaacca ccacccctca t 21 511 21 DNA Homo sapiens 511 cctcaaccac cacccctcat c 21 512 21 DNA Homo sapiens 512 ctcaaccacc ccccctcatc a 21 513 21 DNA Homo sapiens 513 tcaaccacca cccctcatca t 21 514 21 DNA Homo sapiens 514 caaccaccac ccctcatcat a 21 515 21 DNA Homo sapiens 515 aaccaccacc cctcatcata c 21 516 21 DNA Homo sapiens 516 accaccaccc ctcatcatac c 21 517 21 DNA Homo sapiens 517 ccaccacccc ccatcatacc t 21 518 21 DNA Homo sapiens 518 caccacccct catcatacct c 21 519 21 DNA Homo sapiens 519 accacccctc ctcatacctc a 21 520 21 DNA Homo sapiens 520 ccacccctca ccatacctca a 21 521 20 DNA Homo sapiens 521 atatagtttc gtcattcatc 20 522 20 DNA Homo sapiens 522 tacattgccc atgtaattaa 20 523 20 DNA Homo sapiens 523 atatagtttc gtcattcatc 20 524 20 DNA Homo sapiens 524 tacattgccc atgtaattaa 20 525 20 DNA Homo sapiens 525 agatagtttc gtcattcatc 20 526 20 DNA Homo sapiens 526 agatagtttc ctcattcatc 20 527 20 DNA Homo sapiens 527 agatagtttc gccattcatc 20 528 20 DNA Homo sapiens 528 agatagtttc gtcattcatc 20 529 21 DNA Homo sapiens 529 cacccctcat catacctcaa a 21 530 21 DNA Homo sapiens 530 acccctcatc ctacctcaaa a 21 531 21 DNA Homo sapiens 531 cccctcatca cacctcaaaa a 21 532 21 DNA Homo sapiens 532 ccctcatcat ccctcaaaaa c 21 533 21 DNA Homo sapiens 533 cctcatcata cctcaaaaac c 21 534 21 DNA Homo sapiens 534 ctcatcatac ctcaaaaacc a 21 535 21 DNA Homo sapiens 535 tcatcatacc ccaaaaacca a 21 536 21 DNA Homo sapiens 536 catcatacct caaaaaccaa c 21 537 21 DNA Homo sapiens 537 atcatacctc caaaaccaac t 21 538 21 DNA Homo sapiens 538 tcatacctca caaaccaact a 21 539 21 DNA Homo sapiens 539 catacctcaa caaccaacta a 21 540 21 DNA Homo sapiens 540 atacctcaaa caccaactaa c 21 541 21 DNA Homo sapiens 541 atcatacctc aaccaccacc c 21 542 21 DNA Homo sapiens 542 tcatacctca accaccaccc c 21 543 21 DNA Homo sapiens 543 catacctcaa acaccacccc t 21 544 21 DNA Homo sapiens 544 atacctcaac aaccacccct c 21 545 21 DNA Homo sapiens 545 tacctcaacc accacccctc a 21 546 21 DNA Homo sapiens 546 acctcaacca acacccctca t 21 547 21 DNA Homo sapiens 547 cctcaaccac aacccctcat c 21 548 21 DNA Homo sapiens 548 ctcaaccacc acccctcatc a 21 549 21 DNA Homo sapiens 549 tcaaccacca accctcatca t 21 550 21 DNA Homo sapiens 550 caaccaccac acctcatcat a 21 551 21 DNA Homo sapiens 551 aaccaccacc actcatcata c 21 552 21 DNA Homo sapiens 552 accaccaccc atcatcatac c 21 553 21 DNA Homo sapiens 553 ccaccacccc acatcatacc t 21 554 21 DNA Homo sapiens 554 caccacccct aatcatacct c 21 555 21 DNA Homo sapiens 555 accacccctc atcatacctc a 21 556 21 DNA Homo sapiens 556 ccacccctca acatacctca a 21 557 20 DNA Homo sapiens 557 tacattgccc atgtaattaa 20 558 20 DNA Homo sapiens 558 atatagtttc gtcattcatc 20 559 20 DNA Homo sapiens 559 tacattgccc atgtaattaa 20 560 20 DNA Homo sapiens 560 atatagtttc gtcattcatc 20 561 20 DNA Homo sapiens 561 agatagttta gtcattcatc 20 562 20 DNA Homo sapiens 562 agatagtttc atcattcatc 20 563 20 DNA Homo sapiens 563 agatagtttc gacattcatc 20 564 20 DNA Homo sapiens 564 agatagtttc gtaattcatc 20 565 21 DNA Homo sapiens 565 cacccctcat aatacctcaa a 21 566 21 DNA Homo sapiens 566 acccctcatc atacctcaaa a 21 567 21 DNA Homo sapiens 567 cccctcatca aacctcaaaa a 21 568 21 DNA Homo sapiens 568 ccctcatcat acctcaaaaa c 21 569 21 DNA Homo sapiens 569 cctcatcata actcaaaaac c 21 570 21 DNA Homo sapiens 570 ctcatcatac atcaaaaacc a 21 571 21 DNA Homo sapiens 571 tcatcatacc acaaaaacca a 21 572 21 DNA Homo sapiens 572 catcatacct aaaaaaccaa c 21 573 21 DNA Homo sapiens 573 atcatacctc aaaaaccaac t 21 574 21 DNA Homo sapiens 574 tcatacctca aaaaccaact a 21 575 21 DNA Homo sapiens 575 catacctcaa aaaccaacta a 21 576 21 DNA Homo sapiens 576 atacctcaaa aaccaactaa c 21 577 21 DNA Homo sapiens 577 tacctcaaaa tccaactaac c 21 578 21 DNA Homo sapiens 578 acctcaaaaa tcaactaacc a 21 579 21 DNA Homo sapiens 579 cctcaaaaac taactaacca a 21 580 21 DNA Homo sapiens 580 ctcaaaaacc tactaaccaa c 21 581 21 DNA Homo sapiens 581 tcaaaaacca tctaaccaac c 21 582 21 DNA Homo sapiens 582 caaaaaccaa ttaaccaacc a 21 583 21 DNA Homo sapiens 583 aaaaaccaac taaccaacca a 21 584 21 DNA Homo sapiens 584 aaaaccaact taccaaccaa t 21 585 21 DNA Homo sapiens 585 aaccaaccaa taatctccca c 21 586 21 DNA Homo sapiens 586 accaaccaat tatctcccac c 21 587 21 DNA Homo sapiens 587 ccaaccaata ttctcccacc c 21 588 21 DNA Homo sapiens 588 caaccaataa tctcccaccc c 21 589 21 DNA Homo sapiens 589 aaccaataat ttcccacccc g 21 590 20 DNA Homo sapiens 590 atatagtttc gtcattcatc 20 591 20 DNA Homo sapiens 591 tacattgccc atgtaattaa 20 592 20 DNA Homo sapiens 592 atatagtttc gtcattcatc 20 593 20 DNA Homo sapiens 593 tacattgccc atgtaattaa 20 594 20 DNA Homo sapiens 594 agatagtttt gtcattcatc 20 595 20 DNA Homo sapiens 595 agatagtttc ttcattcatc 20 596 20 DNA Homo sapiens 596 agatagtttc gtcattcatc 20 597 20 DNA Homo sapiens 597 agatagtttc gttattcatc 20 598 21 DNA Homo sapiens 598 accaataatc tcccaccccg c 21 599 21 DNA Homo sapiens 599 ccaataatct tccaccccgc c 21 600 21 DNA Homo sapiens 600 caataatctc tcaccccgcc t 21 601 21 DNA Homo sapiens 601 aataatctcc taccccgcct a 21 602 21 DNA Homo sapiens 602 ataatctccc tccccgccta g 21 603 21 DNA Homo sapiens 603 taatctccca tcccgcctag c 21 604 21 DNA Homo sapiens 604 aatctcccac tccgcctagc t 21 605 21 DNA Homo sapiens 605 atctcccacc tcgcctagct c 21 606 21 DNA Homo sapiens 606 tctcccaccc tgcctagctc a 21 607 21 DNA Homo sapiens 607 ctcccacccc tcctagctca c 21 608 21 DNA Homo sapiens 608 tcccaccccg tctagctcac g 21 609 21 DNA Homo sapiens 609 cccaccccgc ttagctcacg c 21 610 21 DNA Homo sapiens 610 ccaccccgcc tagctcacgc a 21 611 21 DNA Homo sapiens 611 caccccgcct tgctcacgca a 21 612 21 DNA Homo sapiens 612 accccgccta tctcacgcaa g 21 613 21 DNA Homo sapiens 613 tacctcaaaa gccaactaac c 21 614 21 DNA Homo sapiens 614 acctcaaaaa gcaactaacc a 21 615 21 DNA Homo sapiens 615 cctcaaaaac gaactaacca a 21 616 21 DNA Homo sapiens 616 ctcaaaaacc gactaaccaa c 21 617 21 DNA Homo sapiens 617 tcaaaaacca gctaaccaac c 21 618 21 DNA Homo sapiens 618 caaaaaccaa gtaaccaacc a 21 619 21 DNA Homo sapiens 619 aaaaaccaac gaaccaacca a 21 620 21 DNA Homo sapiens 620 aaaaccaact gaccaaccaa t 21 621 21 DNA Homo sapiens 621 aaccaaccaa gaatctccca c 21 622 21 DNA Homo sapiens 622 accaaccaat gatctcccac c 21 623 21 DNA Homo sapiens 623 ccaaccaata gtctcccacc c 21 624 21 DNA Homo sapiens 624 caaccaataa gctcccaccc c 21 625 21 DNA Homo sapiens 625 aaccaataat gtcccacccc g 21 626 20 DNA Homo sapiens 626 tacattgccc atgtaattaa 20 627 20 DNA Homo sapiens 627 atatagtttc gtcattcatc 20 628 20 DNA Homo sapiens 628 tacattgccc atgtaattaa 20 629 20 DNA Homo sapiens 629 atatagtttc gtcattcatc 20 630 20 DNA Homo sapiens 630 agatagtttg gtcattcatc 20 631 20 DNA Homo sapiens 631 agatagtttc gtcattcatc 20 632 20 DNA Homo sapiens 632 agatagtttc ggcattcatc 20 633 20 DNA Homo sapiens 633 agatagtttc gtgattcatc 20 634 21 DNA Homo sapiens 634 accaataatc gcccaccccg c 21 635 21 DNA Homo sapiens 635 ccaataatct gccaccccgc c 21 636 21 DNA Homo sapiens 636 caataatctc gcaccccgcc t 21 637 21 DNA Homo sapiens 637 aataatctcc gaccccgcct a 21 638 21 DNA Homo sapiens 638 ataatctccc gccccgccta g 21 639 21 DNA Homo sapiens 639 taatctccca gcccgcctag c 21 640 21 DNA Homo sapiens 640 aatctcccac gccgcctagc t 21 641 21 DNA Homo sapiens 641 atctcccacc gcgcctagct c 21 642 21 DNA Homo sapiens 642 tctcccaccc ggcctagctc a 21 643 21 DNA Homo sapiens 643 ctcccacccc gcctagctca c 21 644 21 DNA Homo sapiens 644 tcccaccccg gctagctcac g 21 645 21 DNA Homo sapiens 645 cccaccccgc gtagctcacg c 21 646 21 DNA Homo sapiens 646 ccaccccgcc gagctcacgc a 21 647 21 DNA Homo sapiens 647 caccccgcct ggctcacgca a 21 648 21 DNA Homo sapiens 648 accccgccta gctcacgcaa g 21 649 21 DNA Homo sapiens 649 tacctcaaaa cccaactaac c 21 650 21 DNA Homo sapiens 650 acctcaaaaa ccaactaacc a 21 651 21 DNA Homo sapiens 651 cctcaaaaac caactaacca a 21 652 21 DNA Homo sapiens 652 ctcaaaaacc cactaaccaa c 21 653 21 DNA Homo sapiens 653 tcaaaaacca cctaaccaac c 21 654 21 DNA Homo sapiens 654 caaaaaccaa ctaaccaacc a 21 655 21 DNA Homo sapiens 655 aaaaaccaac caaccaacca a 21 656 21 DNA Homo sapiens 656 aaaaccaact caccaaccaa t 21 657 21 DNA Homo sapiens 657 aaccaaccaa caatctccca c 21 658 21 DNA Homo sapiens 658 accaaccaat catctcccac c 21 659 21 DNA Homo sapiens 659 ccaaccaata ctctcccacc c 21 660 21 DNA Homo sapiens 660 caaccaataa cctcccaccc c 21 661 21 DNA Homo sapiens 661 aaccaataat ctcccacccc g 21 662 20 DNA Homo sapiens 662 atatagtttc gtcattcatc 20 663 20 DNA Homo sapiens 663 tacattgccc atgtaattaa 20 664 20 DNA Homo sapiens 664 atatagtttc gtcattcatc 20 665 20 DNA Homo sapiens 665 tacattgccc atgtaattaa 20 666 20 DNA Homo sapiens 666 agatagtttc gtcattcatc 20 667 20 DNA Homo sapiens 667 agatagtttc ctcattcatc 20 668 20 DNA Homo sapiens 668 agatagtttc gccattcatc 20 669 20 DNA Homo sapiens 669 agatagtttc gtcattcatc 20 670 21 DNA Homo sapiens 670 accaataatc ccccaccccg c 21 671 21 DNA Homo sapiens 671 ccaataatct cccaccccgc c 21 672 21 DNA Homo sapiens 672 caataatctc ccaccccgcc t 21 673 21 DNA Homo sapiens 673 aataatctcc caccccgcct a 21 674 21 DNA Homo sapiens 674 ataatctccc cccccgccta g 21 675 21 DNA Homo sapiens 675 taatctccca ccccgcctag c 21 676 21 DNA Homo sapiens 676 aatctcccac cccgcctagc t 21 677 21 DNA Homo sapiens 677 atctcccacc ccgcctagct c 21 678 21 DNA Homo sapiens 678 tctcccaccc cgcctagctc a 21 679 21 DNA Homo sapiens 679 ctcccacccc ccctagctca c 21 680 21 DNA Homo sapiens 680 tcccaccccg cctagctcac g 21 681 21 DNA Homo sapiens 681 cccaccccgc ctagctcacg c 21 682 21 DNA Homo sapiens 682 ccaccccgcc cagctcacgc a 21 683 21 DNA Homo sapiens 683 caccccgcct cgctcacgca a 21 684 21 DNA Homo sapiens 684 accccgccta cctcacgcaa g 21 685 21 DNA Homo sapiens 685 tacctcaaaa accaactaac c 21 686 21 DNA Homo sapiens 686 acctcaaaaa acaactaacc a 21 687 21 DNA Homo sapiens 687 cctcaaaaac aaactaacca a 21 688 21 DNA Homo sapiens 688 ctcaaaaacc aactaaccaa c 21 689 21 DNA Homo sapiens 689 tcaaaaacca actaaccaac c 21 690 21 DNA Homo sapiens 690 caaaaaccaa ataaccaacc a 21 691 21 DNA Homo sapiens 691 aaaaaccaac aaaccaacca a 21 692 21 DNA Homo sapiens 692 aaaaccaact aaccaaccaa t 21 693 21 DNA Homo sapiens 693 aaccaaccaa aaatctccca c 21 694 21 DNA Homo sapiens 694 accaaccaat aatctcccac c 21 695 21 DNA Homo sapiens 695 ccaaccaata atctcccacc c 21 696 21 DNA Homo sapiens 696 caaccaataa actcccaccc c 21 697 21 DNA Homo sapiens 697 aaccaataat atcccacccc g 21 698 20 DNA Homo sapiens 698 tacattgccc atgtaattaa 20 699 20 DNA Homo sapiens 699 atatagtttc gtcattcatc 20 700 20 DNA Homo sapiens 700 tacattgccc atgtaattaa 20 701 20 DNA Homo sapiens 701 atatagtttc gtcattcatc 20 702 20 DNA Homo sapiens 702 agatagttta gtcattcatc 20 703 20 DNA Homo sapiens 703 agatagtttc atcattcatc 20 704 20 DNA Homo sapiens 704 agatagtttc gacattcatc 20 705 20 DNA Homo sapiens 705 agatagtttc gtaattcatc 20 706 21 DNA Homo sapiens 706 accaataatc acccaccccg c 21 707 21 DNA Homo sapiens 707 ccaataatct accaccccgc c 21 708 21 DNA Homo sapiens 708 caataatctc acaccccgcc t 21 709 21 DNA Homo sapiens 709 aataatctcc aaccccgcct a 21 710 21 DNA Homo sapiens 710 ataatctccc accccgccta g 21 711 21 DNA Homo sapiens 711 taatctccca acccgcctag c 21 712 21 DNA Homo sapiens 712 aatctcccac accgcctagc t 21 713 21 DNA Homo sapiens 713 atctcccacc acgcctagct c 21 714 21 DNA Homo sapiens 714 tctcccaccc agcctagctc a 21 715 21 DNA Homo sapiens 715 ctcccacccc acctagctca c 21 716 21 DNA Homo sapiens 716 tcccaccccg actagctcac g 21 717 21 DNA Homo sapiens 717 cccaccccgc atagctcacg c 21 718 21 DNA Homo sapiens 718 ccaccccgcc aagctcacgc a 21 719 21 DNA Homo sapiens 719 caccccgcct agctcacgca a 21 720 21 DNA Homo sapiens 720 accccgccta actcacgcaa g 21 721 21 DNA Homo sapiens 721 ccccgcctag ttcacgcaag c 21 722 21 DNA Homo sapiens 722 cccgcctagc tcacgcaagc c 21 723 21 DNA Homo sapiens 723 ccgcctagct tacgcaagcc g 21 724 21 DNA Homo sapiens 724 cgcctagctc tcgcaagccg c 21 725 21 DNA Homo sapiens 725 gcctagctca tgcaagccgc c 21 726 21 DNA Homo sapiens 726 cctagctcac tcaagccgcc a 21 727 21 DNA Homo sapiens 727 ctagctcacg taagccgcca a 21 728 21 DNA Homo sapiens 728 tagctcacgc tagccgccaa c 21 729 21 DNA Homo sapiens 729 agctcacgca tgccgccaac g 21 730 21 DNA Homo sapiens 730 gctcacgcaa tccgccaacg c 21 731 20 DNA Homo sapiens 731 atatagtttc gtcattcatc 20 732 20 DNA Homo sapiens 732 tacattgccc atgtaattaa 20 733 20 DNA Homo sapiens 733 atatagtttc gtcattcatc 20 734 20 DNA Homo sapiens 734 tacattgccc atgtaattaa 20 735 20 DNA Homo sapiens 735 agatagtttt gtcattcatc 20 736 20 DNA Homo sapiens 736 agatagtttc ttcattcatc 20 737 20 DNA Homo sapiens 737 agatagtttc gtcattcatc 20 738 20 DNA Homo sapiens 738 agatagtttc gttattcatc 20 739 21 DNA Homo sapiens 739 ctcacgcaag tcgccaacgc c 21 740 21 DNA Homo sapiens 740 tcacgcaagc tgccaacgcc t 21 741 21 DNA Homo sapiens 741 cacgcaagcc tccaacgcct c 21 742 21 DNA Homo sapiens 742 acgcaagccg tcaacgcctc t 21 743 21 DNA Homo sapiens 743 cgcaagccgc taacgcctct c 21 744 21 DNA Homo sapiens 744 gcaagccgcc tacgcctctc c 21 745 21 DNA Homo sapiens 745 caagccgcca tcgcctctcc c 21 746 21 DNA Homo sapiens 746 aagccgccaa tgcctctccc c 21 747 21 DNA Homo sapiens 747 agccgccaac tcctctcccc c 21 748 21 DNA Homo sapiens 748 gccgccaacg tctctccccc t 21 749 21 DNA Homo sapiens 749 ccgccaacgc ttctccccct c 21 750 21 DNA Homo sapiens 750 cgccaacgcc tctccccctc t 21 751 21 DNA Homo sapiens 751 gccaacgcct ttccccctct c 21 752 21 DNA Homo sapiens 752 ccaacgcctc tccccctctc a 21 753 21 DNA Homo sapiens 753 caacgcctct tcccctctca t 21 754 21 DNA Homo sapiens 754 aacgcctctc tccctctcat c 21 755 21 DNA Homo sapiens 755 acgcctctcc tcctctcatc c 21 756 21 DNA Homo sapiens 756 cgcctctccc tctctcatcc a 21 757 21 DNA Homo sapiens 757 ccccgcctag gtcacgcaag c 21 758 21 DNA Homo sapiens 758 cccgcctagc gcacgcaagc c 21 759 21 DNA Homo sapiens 759 ccgcctagct gacgcaagcc g 21 760 21 DNA Homo sapiens 760 cgcctagctc gcgcaagccg c 21 761 21 DNA Homo sapiens 761 gcctagctca ggcaagccgc c 21 762 21 DNA Homo sapiens 762 cctagctcac gcaagccgcc a 21 763 21 DNA Homo sapiens 763 ctagctcacg gaagccgcca a 21 764 21 DNA Homo sapiens 764 tagctcacgc gagccgccaa c 21 765 21 DNA Homo sapiens 765 agctcacgca ggccgccaac g 21 766 21 DNA Homo sapiens 766 gctcacgcaa gccgccaacg c 21 767 20 DNA Homo sapiens 767 tacattgccc atgtaattaa 20 768 20 DNA Homo sapiens 768 atatagtttc gtcattcatc 20 769 20 DNA Homo sapiens 769 tacattgccc atgtaattaa 20 770 20 DNA Homo sapiens 770 atatagtttc gtcattcatc 20 771 20 DNA Homo sapiens 771 agatagtttg gtcattcatc 20 772 20 DNA Homo sapiens 772 agatagtttc gtcattcatc 20 773 20 DNA Homo sapiens 773 agatagtttc ggcattcatc 20 774 20 DNA Homo sapiens 774 agatagtttc gtgattcatc 20 775 21 DNA Homo sapiens 775 ctcacgcaag gcgccaacgc c 21 776 21 DNA Homo sapiens 776 tcacgcaagc ggccaacgcc t 21 777 21 DNA Homo sapiens 777 cacgcaagcc gccaacgcct c 21 778 21 DNA Homo sapiens 778 acgcaagccg gcaacgcctc t 21 779 21 DNA Homo sapiens 779 cgcaagccgc gaacgcctct c 21 780 21 DNA Homo sapiens 780 gcaagccgcc gacgcctctc c 21 781 21 DNA Homo sapiens 781 caagccgcca gcgcctctcc c 21 782 21 DNA Homo sapiens 782 aagccgccaa ggcctctccc c 21 783 21 DNA Homo sapiens 783 agccgccaac gcctctcccc c 21 784 21 DNA Homo sapiens 784 gccgccaacg gctctccccc t 21 785 21 DNA Homo sapiens 785 ccgccaacgc gtctccccct c 21 786 21 DNA Homo sapiens 786 cgccaacgcc gctccccctc t 21 787 21 DNA Homo sapiens 787 gccaacgcct gtccccctct c 21 788 21 DNA Homo sapiens 788 ccaacgcctc gccccctctc a 21 789 21 DNA Homo sapiens 789 caacgcctct gcccctctca t 21 790 21 DNA Homo sapiens 790 aacgcctctc gccctctcat c 21 791 21 DNA Homo sapiens 791 acgcctctcc gcctctcatc c 21 792 21 DNA Homo sapiens 792 cgcctctccc gctctcatcc a 21 793 21 DNA Homo sapiens 793 ccccgcctag ctcacgcaag c 21 794 21 DNA Homo sapiens 794 cccgcctagc ccacgcaagc c 21 795 21 DNA Homo sapiens 795 ccgcctagct cacgcaagcc g 21 796 21 DNA Homo sapiens 796 cgcctagctc ccgcaagccg c 21 797 21 DNA Homo sapiens 797 gcctagctca cgcaagccgc c 21 798 21 DNA Homo sapiens 798 cctagctcac ccaagccgcc a 21 799 21 DNA Homo sapiens 799 ctagctcacg caagccgcca a 21 800 21 DNA Homo sapiens 800 tagctcacgc cagccgccaa c 21 801 21 DNA Homo sapiens 801 agctcacgca cgccgccaac g 21 802 21 DNA Homo sapiens 802 gctcacgcaa cccgccaacg c 21 803 20 DNA Homo sapiens 803 atatagtttc gtcattcatc 20 804 20 DNA Homo sapiens 804 tacattgccc atgtaattaa 20 805 20 DNA Homo sapiens 805 atatagtttc gtcattcatc 20 806 20 DNA Homo sapiens 806 tacattgccc atgtaattaa 20 807 20 DNA Homo sapiens 807 agatagtttc gtcattcatc 20 808 20 DNA Homo sapiens 808 agatagtttc ctcattcatc 20 809 20 DNA Homo sapiens 809 agatagtttc gccattcatc 20 810 20 DNA Homo sapiens 810 agatagtttc gtcattcatc 20 811 21 DNA Homo sapiens 811 ctcacgcaag ccgccaacgc c 21 812 21 DNA Homo sapiens 812 tcacgcaagc cgccaacgcc t 21 813 21 DNA Homo sapiens 813 cacgcaagcc cccaacgcct c 21 814 21 DNA Homo sapiens 814 acgcaagccg ccaacgcctc t 21 815 21 DNA Homo sapiens 815 cgcaagccgc caacgcctct c 21 816 21 DNA Homo sapiens 816 gcaagccgcc cacgcctctc c 21 817 21 DNA Homo sapiens 817 caagccgcca ccgcctctcc c 21 818 21 DNA Homo sapiens 818 aagccgccaa cgcctctccc c 21 819 21 DNA Homo sapiens 819 agccgccaac ccctctcccc c 21 820 21 DNA Homo sapiens 820 gccgccaacg cctctccccc t 21 821 21 DNA Homo sapiens 821 ccgccaacgc ctctccccct c 21 822 21 DNA Homo sapiens 822 cgccaacgcc cctccccctc t 21 823 21 DNA Homo sapiens 823 gccaacgcct ctccccctct c 21 824 21 DNA Homo sapiens 824 ccaacgcctc cccccctctc a 21 825 21 DNA Homo sapiens 825 caacgcctct ccccctctca t 21 826 21 DNA Homo sapiens 826 aacgcctctc cccctctcat c 21 827 21 DNA Homo sapiens 827 acgcctctcc ccctctcatc c 21 828 21 DNA Homo sapiens 828 cgcctctccc cctctcatcc a 21 829 21 DNA Homo sapiens 829 ccccgcctag atcacgcaag c 21 830 21 DNA Homo sapiens 830 cccgcctagc acacgcaagc c 21 831 21 DNA Homo sapiens 831 ccgcctagct aacgcaagcc g 21 832 21 DNA Homo sapiens 832 cgcctagctc acgcaagccg c 21 833 21 DNA Homo sapiens 833 gcctagctca agcaagccgc c 21 834 21 DNA Homo sapiens 834 cctagctcac acaagccgcc a 21 835 21 DNA Homo sapiens 835 ctagctcacg aaagccgcca a 21 836 21 DNA Homo sapiens 836 tagctcacgc aagccgccaa c 21 837 21 DNA Homo sapiens 837 agctcacgca agccgccaac g 21 838 21 DNA Homo sapiens 838 gctcacgcaa accgccaacg c 21 839 20 DNA Homo sapiens 839 tacattgccc atgtaattaa 20 840 20 DNA Homo sapiens 840 atatagtttc gtcattcatc 20 841 20 DNA Homo sapiens 841 tacattgccc atgtaattaa 20 842 20 DNA Homo sapiens 842 atatagtttc gtcattcatc 20 843 20 DNA Homo sapiens 843 agatagttta gtcattcatc 20 844 20 DNA Homo sapiens 844 agatagtttc atcattcatc 20 845 20 DNA Homo sapiens 845 agatagtttc gacattcatc 20 846 20 DNA Homo sapiens 846 agatagtttc gtaattcatc 20 847 21 DNA Homo sapiens 847 ctcacgcaag acgccaacgc c 21 848 21 DNA Homo sapiens 848 tcacgcaagc agccaacgcc t 21 849 21 DNA Homo sapiens 849 cacgcaagcc accaacgcct c 21 850 21 DNA Homo sapiens 850 acgcaagccg acaacgcctc t 21 851 21 DNA Homo sapiens 851 cgcaagccgc aaacgcctct c 21 852 21 DNA Homo sapiens 852 gcaagccgcc aacgcctctc c 21 853 21 DNA Homo sapiens 853 caagccgcca acgcctctcc c 21 854 21 DNA Homo sapiens 854 aagccgccaa agcctctccc c 21 855 21 DNA Homo sapiens 855 agccgccaac acctctcccc c 21 856 21 DNA Homo sapiens 856 gccgccaacg actctccccc t 21 857 21 DNA Homo sapiens 857 ccgccaacgc atctccccct c 21 858 21 DNA Homo sapiens 858 cgccaacgcc actccccctc t 21 859 21 DNA Homo sapiens 859 gccaacgcct atccccctct c 21 860 21 DNA Homo sapiens 860 ccaacgcctc accccctctc a 21 861 21 DNA Homo sapiens 861 caacgcctct acccctctca t 21 862 21 DNA Homo sapiens 862 aacgcctctc accctctcat c 21 863 21 DNA Homo sapiens 863 acgcctctcc acctctcatc c 21 864 21 DNA Homo sapiens 864 cgcctctccc actctcatcc a 21 865 21 DNA Homo sapiens 865 gcctctcccc ttctcatcca t 21 866 21 DNA Homo sapiens 866 cctctccccc tctcatccat c 21 867 21 DNA Homo sapiens 867 ctctccccct ttcatccatc g 21 868 21 DNA Homo sapiens 868 tctccccctc tcatccatcg c 21 869 21 DNA Homo sapiens 869 ctccccctct tatccatcgc c 21 870 21 DNA Homo sapiens 870 tccccctctc ttccatcgcc c 21 871 21 DNA Homo sapiens 871 ccccctctca tccatcgccc g 21 872 20 DNA Homo sapiens 872 atatagtttc gtcattcatc 20 873 20 DNA Homo sapiens 873 tacattgccc atgtaattaa 20 874 20 DNA Homo sapiens 874 atatagtttc gtcattcatc 20 875 20 DNA Homo sapiens 875 tacattgccc atgtaattaa 20 876 20 DNA Homo sapiens 876 agatagtttt gtcattcatc 20 877 20 DNA Homo sapiens 877 agatagtttc ttcattcatc 20 878 20 DNA Homo sapiens 878 agatagtttc gtcattcatc 20 879 20 DNA Homo sapiens 879 agatagtttc gttattcatc 20 880 21 DNA Homo sapiens 880 cccctctcat tcatcgcccg c 21 881 21 DNA Homo sapiens 881 ccctctcatc tatcgcccgc c 21 882 21 DNA Homo sapiens 882 cctctcatcc ttcgcccgcc g 21 883 21 DNA Homo sapiens 883 ctctcatcca tcgcccgccg c 21 884 21 DNA Homo sapiens 884 tctcatccat tgcccgccgc c 21 885 21 DNA Homo sapiens 885 ctcatccatc tcccgccgcc c 21 886 21 DNA Homo sapiens 886 tcatccatcg tccgccgccc c 21 887 21 DNA Homo sapiens 887 catccatcgc tcgccgcccc t 21 888 21 DNA Homo sapiens 888 atccatcgcc tgccgcccct c 21 889 21 DNA Homo sapiens 889 tccatcgccc tccgcccctc a 21 890 21 DNA Homo sapiens 890 ccatcgcccg tcgcccctca t 21 891 21 DNA Homo sapiens 891 catcgcccgc tgcccctcat c 21 892 21 DNA Homo sapiens 892 atcgcccgcc tcccctcatc a 21 893 21 DNA Homo sapiens 893 tcgcccgccg tccctcatca t 21 894 21 DNA Homo sapiens 894 cgcccgccgc tcctcatcat a 21 895 21 DNA Homo sapiens 895 gcccgccgcc tctcatcata c 21 896 21 DNA Homo sapiens 896 cccgccgccc ttcatcatac c 21 897 21 DNA Homo sapiens 897 ccgccgcccc tcatcatacc t 21 898 21 DNA Homo sapiens 898 cgccgcccct tatcatacct c 21 899 21 DNA Homo sapiens 899 gccgcccctc ttcatacctc a 21 900 21 DNA Homo sapiens 900 ccgcccctca tcatacctca g 21 901 21 DNA Homo sapiens 901 gcctctcccc gtctcatcca t 21 902 21 DNA Homo sapiens 902 cctctccccc gctcatccat c 21 903 21 DNA Homo sapiens 903 ctctccccct gtcatccatc g 21 904 21 DNA Homo sapiens 904 tctccccctc gcatccatcg c 21 905 21 DNA Homo sapiens 905 ctccccctct gatccatcgc c 21 906 21 DNA Homo sapiens 906 tccccctctc gtccatcgcc c 21 907 21 DNA Homo sapiens 907 ccccctctca gccatcgccc g 21 908 20 DNA Homo sapiens 908 tacattgccc atgtaattaa 20 909 20 DNA Homo sapiens 909 atatagtttc gtcattcatc 20 910 20 DNA Homo sapiens 910 tacattgccc atgtaattaa 20 911 20 DNA Homo sapiens 911 atatagtttc gtcattcatc 20 912 20 DNA Homo sapiens 912 agatagtttg gtcattcatc 20 913 20 DNA Homo sapiens 913 agatagtttc gtcattcatc 20 914 20 DNA Homo sapiens 914 agatagtttc ggcattcatc 20 915 20 DNA Homo sapiens 915 agatagtttc gtgattcatc 20 916 21 DNA Homo sapiens 916 cccctctcat gcatcgcccg c 21 917 21 DNA Homo sapiens 917 ccctctcatc gatcgcccgc c 21 918 21 DNA Homo sapiens 918 cctctcatcc gtcgcccgcc g 21 919 21 DNA Homo sapiens 919 ctctcatcca gcgcccgccg c 21 920 21 DNA Homo sapiens 920 tctcatccat ggcccgccgc c 21 921 21 DNA Homo sapiens 921 ctcatccatc gcccgccgcc c 21 922 21 DNA Homo sapiens 922 tcatccatcg gccgccgccc c 21 923 21 DNA Homo sapiens 923 catccatcgc gcgccgcccc t 21 924 21 DNA Homo sapiens 924 atccatcgcc ggccgcccct c 21 925 21 DNA Homo sapiens 925 tccatcgccc gccgcccctc a 21 926 21 DNA Homo sapiens 926 ccatcgcccg gcgcccctca t 21 927 21 DNA Homo sapiens 927 catcgcccgc ggcccctcat c 21 928 21 DNA Homo sapiens 928 atcgcccgcc gcccctcatc a 21 929 21 DNA Homo sapiens 929 tcgcccgccg gccctcatca t 21 930 21 DNA Homo sapiens 930 cgcccgccgc gcctcatcat a 21 931 21 DNA Homo sapiens 931 gcccgccgcc gctcatcata c 21 932 21 DNA Homo sapiens 932 cccgccgccc gtcatcatac c 21 933 21 DNA Homo sapiens 933 ccgccgcccc gcatcatacc t 21 934 21 DNA Homo sapiens 934 cgccgcccct gatcatacct c 21 935 21 DNA Homo sapiens 935 gccgcccctc gtcatacctc a 21 936 21 DNA Homo sapiens 936 ccgcccctca gcatacctca g 21 937 21 DNA Homo sapiens 937 gcctctcccc ctctcatcca t 21 938 21 DNA Homo sapiens 938 cctctccccc cctcatccat c 21 939 21 DNA Homo sapiens 939 ctctccccct ctcatccatc g 21 940 21 DNA Homo sapiens 940 tctccccctc ccatccatcg c 21 941 21 DNA Homo sapiens 941 ctccccctct catccatcgc c 21 942 21 DNA Homo sapiens 942 tccccctctc ctccatcgcc c 21 943 21 DNA Homo sapiens 943 ccccctctca cccatcgccc g 21 944 20 DNA Homo sapiens 944 atatagtttc gtcattcatc 20 945 20 DNA Homo sapiens 945 tacattgccc atgtaattaa 20 946 20 DNA Homo sapiens 946 atatagtttc gtcattcatc 20 947 20 DNA Homo sapiens 947 tacattgccc atgtaattaa 20 948 20 DNA Homo sapiens 948 agatagtttc gtcattcatc 20 949 20 DNA Homo sapiens 949 agatagtttc ctcattcatc 20 950 20 DNA Homo sapiens 950 agatagtttc gccattcatc 20 951 20 DNA Homo sapiens 951 agatagtttc gtcattcatc 20 952 21 DNA Homo sapiens 952 cccctctcat ccatcgcccg c 21 953 21 DNA Homo sapiens 953 ccctctcatc catcgcccgc c 21 954 21 DNA Homo sapiens 954 cctctcatcc ctcgcccgcc g 21 955 21 DNA Homo sapiens 955 ctctcatcca ccgcccgccg c 21 956 21 DNA Homo sapiens 956 tctcatccat cgcccgccgc c 21 957 21 DNA Homo sapiens 957 ctcatccatc ccccgccgcc c 21 958 21 DNA Homo sapiens 958 tcatccatcg cccgccgccc c 21 959 21 DNA Homo sapiens 959 catccatcgc ccgccgcccc t 21 960 21 DNA Homo sapiens 960 atccatcgcc cgccgcccct c 21 961 21 DNA Homo sapiens 961 tccatcgccc cccgcccctc a 21 962 21 DNA Homo sapiens 962 ccatcgcccg ccgcccctca t 21 963 21 DNA Homo sapiens 963 catcgcccgc cgcccctcat c 21 964 21 DNA Homo sapiens 964 atcgcccgcc ccccctcatc a 21 965 21 DNA Homo sapiens 965 tcgcccgccg cccctcatca t 21 966 21 DNA Homo sapiens 966 cgcccgccgc ccctcatcat a 21 967 21 DNA Homo sapiens 967 gcccgccgcc cctcatcata c 21 968 21 DNA Homo sapiens 968 cccgccgccc ctcatcatac c 21 969 21 DNA Homo sapiens 969 ccgccgcccc ccatcatacc t 21 970 21 DNA Homo sapiens 970 cgccgcccct catcatacct c 21 971 21 DNA Homo sapiens 971 gccgcccctc ctcatacctc a 21 972 21 DNA Homo sapiens 972 ccgcccctca ccatacctca g 21 973 21 DNA Homo sapiens 973 gcctctcccc atctcatcca t 21 974 21 DNA Homo sapiens 974 cctctccccc actcatccat c 21 975 21 DNA Homo sapiens 975 ctctccccct atcatccatc g 21 976 21 DNA Homo sapiens 976 tctccccctc acatccatcg c 21 977 21 DNA Homo sapiens 977 ctccccctct aatccatcgc c 21 978 21 DNA Homo sapiens 978 tccccctctc atccatcgcc c 21 979 21 DNA Homo sapiens 979 ccccctctca accatcgccc g 21 980 20 DNA Homo sapiens 980 tacattgccc atgtaattaa 20 981 20 DNA Homo sapiens 981 atatagtttc gtcattcatc 20 982 20 DNA Homo sapiens 982 tacattgccc atgtaattaa 20 983 20 DNA Homo sapiens 983 atatagtttc gtcattcatc 20 984 20 DNA Homo sapiens 984 agatagttta gtcattcatc 20 985 20 DNA Homo sapiens 985 agatagtttc atcattcatc 20 986 20 DNA Homo sapiens 986 agatagtttc gacattcatc 20 987 20 DNA Homo sapiens 987 agatagtttc gtaattcatc 20 988 21 DNA Homo sapiens 988 cccctctcat acatcgcccg c 21 989 21 DNA Homo sapiens 989 ccctctcatc aatcgcccgc c 21 990 21 DNA Homo sapiens 990 cctctcatcc atcgcccgcc g 21 991 21 DNA Homo sapiens 991 ctctcatcca acgcccgccg c 21 992 21 DNA Homo sapiens 992 tctcatccat agcccgccgc c 21 993 21 DNA Homo sapiens 993 ctcatccatc acccgccgcc c 21 994 21 DNA Homo sapiens 994 tcatccatcg accgccgccc c 21 995 21 DNA Homo sapiens 995 catccatcgc acgccgcccc t 21 996 21 DNA Homo sapiens 996 atccatcgcc agccgcccct c 21 997 21 DNA Homo sapiens 997 tccatcgccc accgcccctc a 21 998 21 DNA Homo sapiens 998 ccatcgcccg acgcccctca t 21 999 21 DNA Homo sapiens 999 catcgcccgc agcccctcat c 21 1000 21 DNA Homo sapiens 1000 atcgcccgcc acccctcatc a 21 1001 21 DNA Homo sapiens 1001 tcgcccgccg accctcatca t 21 1002 21 DNA Homo sapiens 1002 cgcccgccgc acctcatcat a 21 1003 21 DNA Homo sapiens 1003 gcccgccgcc actcatcata c 21 1004 21 DNA Homo sapiens 1004 cccgccgccc atcatcatac c 21 1005 21 DNA Homo sapiens 1005 ccgccgcccc acatcatacc t 21 1006 21 DNA Homo sapiens 1006 cgccgcccct aatcatacct c 21 1007 21 DNA Homo sapiens 1007 gccgcccctc atcatacctc a 21 1008 21 DNA Homo sapiens 1008 ccgcccctca acatacctca g 21 1009 21 DNA Homo sapiens 1009 cgcccctcat tatacctcag c 21 1010 21 DNA Homo sapiens 1010 gcccctcatc ttacctcagc c 21 1011 21 DNA Homo sapiens 1011 cccctcatca tacctcagcc g 21 1012 21 DNA Homo sapiens 1012 ccctcatcat tcctcagccg c 21 1013 20 DNA Homo sapiens 1013 atatagtttc gtcattcatc 20 1014 20 DNA Homo sapiens 1014 tacattgccc atgtaattaa 20 1015 20 DNA Homo sapiens 1015 atatagtttc gtcattcatc 20 1016 20 DNA Homo sapiens 1016 tacattgccc atgtaattaa 20 1017 20 DNA Homo sapiens 1017 agatagtttt gtcattcatc 20 1018 20 DNA Homo sapiens 1018 agatagtttc ttcattcatc 20 1019 20 DNA Homo sapiens 1019 agatagtttc gtcattcatc 20 1020 20 DNA Homo sapiens 1020 agatagtttc gttattcatc 20 1021 21 DNA Homo sapiens 1021 cctcatcata tctcagccgc c 21 1022 21 DNA Homo sapiens 1022 ctcatcatac ttcagccgcc g 21 1023 21 DNA Homo sapiens 1023 tcatcatacc tcagccgccg c 21 1024 21 DNA Homo sapiens 1024 catcatacct tagccgccgc c 21 1025 21 DNA Homo sapiens 1025 atcatacctc tgccgccgcc c 21 1026 21 DNA Homo sapiens 1026 tcatacctca tccgccgccc c 21 1027 21 DNA Homo sapiens 1027 catacctcag tcgccgcccc t 21 1028 21 DNA Homo sapiens 1028 atacctcagc tgccgcccct c 21 1029 21 DNA Homo sapiens 1029 tacctcagcc tccgcccctc a 21 1030 21 DNA Homo sapiens 1030 acctcagccg tcgcccctca t 21 1031 21 DNA Homo sapiens 1031 cctcagccgc tgcccctcat c 21 1032 21 DNA Homo sapiens 1032 ctcagccgcc tcccctcatc a 21 1033 21 DNA Homo sapiens 1033 tcagccgccg tccctcatca t 21 1034 21 DNA Homo sapiens 1034 cagccgccgc tcctcatcat a 21 1035 21 DNA Homo sapiens 1035 agccgccgcc tctcatcata c 21 1036 21 DNA Homo sapiens 1036 gccgccgccc ttcatcatac c 21 1037 21 DNA Homo sapiens 1037 ccgccgcccc tcatcatacc t 21 1038 21 DNA Homo sapiens 1038 cgccgcccct tatcatacct c 21 1039 21 DNA Homo sapiens 1039 gccgcccctc ttcatacctc a 21 1040 21 DNA Homo sapiens 1040 ccgcccctca tcatacctca a 21 1041 21 DNA Homo sapiens 1041 cgcccctcat tatacctcaa a 21 1042 21 DNA Homo sapiens 1042 gcccctcatc ttacctcaaa a 21 1043 21 DNA Homo sapiens 1043 cccctcatca tacctcaaaa g 21 1044 21 DNA Homo sapiens 1044 ccctcatcat tcctcaaaag c 21 1045 21 DNA Homo sapiens 1045 cgcccctcat gatacctcag c 21 1046 21 DNA Homo sapiens 1046 gcccctcatc gtacctcagc c 21 1047 21 DNA Homo sapiens 1047 cccctcatca gacctcagcc g 21 1048 21 DNA Homo sapiens 1048 ccctcatcat gcctcagccg c 21 1049 20 DNA Homo sapiens 1049 tacattgccc atgtaattaa 20 1050 20 DNA Homo sapiens 1050 atatagtttc gtcattcatc 20 1051 20 DNA Homo sapiens 1051 tacattgccc atgtaattaa 20 1052 20 DNA Homo sapiens 1052 atatagtttc gtcattcatc 20 1053 20 DNA Homo sapiens 1053 agatagtttg gtcattcatc 20 1054 20 DNA Homo sapiens 1054 agatagtttc gtcattcatc 20 1055 20 DNA Homo sapiens 1055 agatagtttc ggcattcatc 20 1056 20 DNA Homo sapiens 1056 agatagtttc gtgattcatc 20 1057 21 DNA Homo sapiens 1057 cctcatcata gctcagccgc c 21 1058 21 DNA Homo sapiens 1058 ctcatcatac gtcagccgcc g 21 1059 21 DNA Homo sapiens 1059 tcatcatacc gcagccgccg c 21 1060 21 DNA Homo sapiens 1060 catcatacct gagccgccgc c 21 1061 21 DNA Homo sapiens 1061 atcatacctc ggccgccgcc c 21 1062 21 DNA Homo sapiens 1062 tcatacctca gccgccgccc c 21 1063 21 DNA Homo sapiens 1063 catacctcag gcgccgcccc t 21 1064 21 DNA Homo sapiens 1064 atacctcagc ggccgcccct c 21 1065 21 DNA Homo sapiens 1065 tacctcagcc gccgcccctc a 21 1066 21 DNA Homo sapiens 1066 acctcagccg gcgcccctca t 21 1067 21 DNA Homo sapiens 1067 cctcagccgc ggcccctcat c 21 1068 21 DNA Homo sapiens 1068 ctcagccgcc gcccctcatc a 21 1069 21 DNA Homo sapiens 1069 tcagccgccg gccctcatca t 21 1070 21 DNA Homo sapiens 1070 cagccgccgc gcctcatcat a 21 1071 21 DNA Homo sapiens 1071 agccgccgcc gctcatcata c 21 1072 21 DNA Homo sapiens 1072 gccgccgccc gtcatcatac c 21 1073 21 DNA Homo sapiens 1073 ccgccgcccc gcatcatacc t 21 1074 21 DNA Homo sapiens 1074 cgccgcccct gatcatacct c 21 1075 21 DNA Homo sapiens 1075 gccgcccctc gtcatacctc a 21 1076 21 DNA Homo sapiens 1076 ccgcccctca gcatacctca a 21 1077 21 DNA Homo sapiens 1077 cgcccctcat gatacctcaa a 21 1078 21 DNA Homo sapiens 1078 gcccctcatc gtacctcaaa a 21 1079 21 DNA Homo sapiens 1079 cccctcatca gacctcaaaa g 21 1080 21 DNA Homo sapiens 1080 ccctcatcat gcctcaaaag c 21 1081 21 DNA Homo sapiens 1081 cgcccctcat catacctcag c 21 1082 21 DNA Homo sapiens 1082 gcccctcatc ctacctcagc c 21 1083 21 DNA Homo sapiens 1083 cccctcatca cacctcagcc g 21 1084 21 DNA Homo sapiens 1084 ccctcatcat ccctcagccg c 21 1085 20 DNA Homo sapiens 1085 atatagtttc gtcattcatc 20 1086 20 DNA Homo sapiens 1086 tacattgccc atgtaattaa 20 1087 20 DNA Homo sapiens 1087 atatagtttc gtcattcatc 20 1088 20 DNA Homo sapiens 1088 tacattgccc atgtaattaa 20 1089 20 DNA Homo sapiens 1089 agatagtttc gtcattcatc 20 1090 20 DNA Homo sapiens 1090 agatagtttc ctcattcatc 20 1091 20 DNA Homo sapiens 1091 agatagtttc gccattcatc 20 1092 20 DNA Homo sapiens 1092 agatagtttc gtcattcatc 20 1093 21 DNA Homo sapiens 1093 cctcatcata cctcagccgc c 21 1094 21 DNA Homo sapiens 1094 ctcatcatac ctcagccgcc g 21 1095 21 DNA Homo sapiens 1095 tcatcatacc ccagccgccg c 21 1096 21 DNA Homo sapiens 1096 catcatacct cagccgccgc c 21 1097 21 DNA Homo sapiens 1097 atcatacctc cgccgccgcc c 21 1098 21 DNA Homo sapiens 1098 tcatacctca cccgccgccc c 21 1099 21 DNA Homo sapiens 1099 catacctcag ccgccgcccc t 21 1100 21 DNA Homo sapiens 1100 atacctcagc cgccgcccct c 21 1101 21 DNA Homo sapiens 1101 tacctcagcc cccgcccctc a 21 1102 21 DNA Homo sapiens 1102 acctcagccg ccgcccctca t 21 1103 21 DNA Homo sapiens 1103 cctcagccgc cgcccctcat c 21 1104 21 DNA Homo sapiens 1104 ctcagccgcc ccccctcatc a 21 1105 21 DNA Homo sapiens 1105 tcagccgccg cccctcatca t 21 1106 21 DNA Homo sapiens 1106 cagccgccgc ccctcatcat a 21 1107 21 DNA Homo sapiens 1107 agccgccgcc cctcatcata c 21 1108 21 DNA Homo sapiens 1108 gccgccgccc ctcatcatac c 21 1109 21 DNA Homo sapiens 1109 ccgccgcccc ccatcatacc t 21 1110 21 DNA Homo sapiens 1110 cgccgcccct catcatacct c 21 1111 21 DNA Homo sapiens 1111 gccgcccctc ctcatacctc a 21 1112 21 DNA Homo sapiens 1112 ccgcccctca ccatacctca a 21 1113 21 DNA Homo sapiens 1113 cgcccctcat catacctcaa a 21 1114 21 DNA Homo sapiens 1114 gcccctcatc ctacctcaaa a 21 1115 21 DNA Homo sapiens 1115 cccctcatca cacctcaaaa g 21 1116 21 DNA Homo sapiens 1116 ccctcatcat ccctcaaaag c 21 1117 21 DNA Homo sapiens 1117 cgcccctcat aatacctcag c 21 1118 21 DNA Homo sapiens 1118 gcccctcatc atacctcagc c 21 1119 21 DNA Homo sapiens 1119 cccctcatca aacctcagcc g 21 1120 21 DNA Homo sapiens 1120 ccctcatcat acctcagccg c 21 1121 20 DNA Homo sapiens 1121 tacattgccc atgtaattaa 20 1122 20 DNA Homo sapiens 1122 atatagtttc gtcattcatc 20 1123 20 DNA Homo sapiens 1123 tacattgccc atgtaattaa 20 1124 20 DNA Homo sapiens 1124 atatagtttc gtcattcatc 20 1125 20 DNA Homo sapiens 1125 agatagttta gtcattcatc 20 1126 20 DNA Homo sapiens 1126 agatagtttc atcattcatc 20 1127 20 DNA Homo sapiens 1127 agatagtttc gacattcatc 20 1128 20 DNA Homo sapiens 1128 agatagtttc gtaattcatc 20 1129 21 DNA Homo sapiens 1129 cctcatcata actcagccgc c 21 1130 21 DNA Homo sapiens 1130 ctcatcatac atcagccgcc g 21 1131 21 DNA Homo sapiens 1131 tcatcatacc acagccgccg c 21 1132 21 DNA Homo sapiens 1132 catcatacct aagccgccgc c 21 1133 21 DNA Homo sapiens 1133 atcatacctc agccgccgcc c 21 1134 21 DNA Homo sapiens 1134 tcatacctca accgccgccc c 21 1135 21 DNA Homo sapiens 1135 catacctcag acgccgcccc t 21 1136 21 DNA Homo sapiens 1136 atacctcagc agccgcccct c 21 1137 21 DNA Homo sapiens 1137 tacctcagcc accgcccctc a 21 1138 21 DNA Homo sapiens 1138 acctcagccg acgcccctca t 21 1139 21 DNA Homo sapiens 1139 cctcagccgc agcccctcat c 21 1140 21 DNA Homo sapiens 1140 ctcagccgcc acccctcatc a 21 1141 21 DNA Homo sapiens 1141 tcagccgccg accctcatca t 21 1142 21 DNA Homo sapiens 1142 cagccgccgc acctcatcat a 21 1143 21 DNA Homo sapiens 1143 agccgccgcc actcatcata c 21 1144 21 DNA Homo sapiens 1144 gccgccgccc atcatcatac c 21 1145 21 DNA Homo sapiens 1145 ccgccgcccc acatcatacc t 21 1146 21 DNA Homo sapiens 1146 cgccgcccct aatcatacct c 21 1147 21 DNA Homo sapiens 1147 gccgcccctc atcatacctc a 21 1148 21 DNA Homo sapiens 1148 ccgcccctca acatacctca a 21 1149 21 DNA Homo sapiens 1149 cgcccctcat aatacctcaa a 21 1150 21 DNA Homo sapiens 1150 gcccctcatc atacctcaaa a 21 1151 21 DNA Homo sapiens 1151 cccctcatca aacctcaaaa g 21 1152 21 DNA Homo sapiens 1152 ccctcatcat acctcaaaag c 21 1153 21 DNA Homo sapiens 1153 cctcatcata tctcaaaagc c 21 1154 20 DNA Homo sapiens 1154 atatagtttc gtcattcatc 20 1155 20 DNA Homo sapiens 1155 tacattgccc atgtaattaa 20 1156 20 DNA Homo sapiens 1156 atatagtttc gtcattcatc 20 1157 20 DNA Homo sapiens 1157 tacattgccc atgtaattaa 20 1158 20 DNA Homo sapiens 1158 agatagtttt gtcattcatc 20 1159 20 DNA Homo sapiens 1159 agatagtttc ttcattcatc 20 1160 20 DNA Homo sapiens 1160 agatagtttc gtcattcatc 20 1161 20 DNA Homo sapiens 1161 agatagtttc gttattcatc 20 1162 21 DNA Homo sapiens 1162 ctcatcatac ttcaaaagcc a 21 1163 21 DNA Homo sapiens 1163 tcatcatacc tcaaaagcca a 21 1164 21 DNA Homo sapiens 1164 catcatacct taaaagccaa c 21 1165 21 DNA Homo sapiens 1165 atcatacctc taaagccaac t 21 1166 21 DNA Homo sapiens 1166 tcatacctca taagccaact a 21 1167 21 DNA Homo sapiens 1167 catacctcaa tagccaacta a 21 1168 21 DNA Homo sapiens 1168 atacctcaaa tgccaactaa c 21 1169 21 DNA Homo sapiens 1169 tacctcaaaa tccaactaac c 21 1170 21 DNA Homo sapiens 1170 acctcaaaag tcaactaacc a 21 1171 21 DNA Homo sapiens 1171 cctcaaaagc taactaacca a 21 1172 21 DNA Homo sapiens 1172 ctcaaaagcc tactaaccaa c 21 1173 21 DNA Homo sapiens 1173 tcaaaagcca tctaaccaac c 21 1174 21 DNA Homo sapiens 1174 caaaagccaa ttaaccaacc a 21 1175 21 DNA Homo sapiens 1175 aaaagccaac taaccaacca a 21 1176 21 DNA Homo sapiens 1176 aaagccaact taccaaccaa t 21 1177 20 DNA Homo sapiens 1177 atatagtttc gtcattcatc 20 1178 20 DNA Homo sapiens 1178 tacattgccc atgtaattaa 20 1179 20 DNA Homo sapiens 1179 atatagtttc gtcattcatc 20 1180 20 DNA Homo sapiens 1180 tacattgccc atgtaattaa 20 1181 20 DNA Homo sapiens 1181 agatagtttt gtcattcatc 20 1182 20 DNA Homo sapiens 1182 agatagtttc ttcattcatc 20 1183 20 DNA Homo sapiens 1183 agatagtttc gtcattcatc 20 1184 20 DNA Homo sapiens 1184 agatagtttc gttattcatc 20 1185 21 DNA Homo sapiens 1185 cctcatcata gctcaaaagc c 21 1186 20 DNA Homo sapiens 1186 tacattgccc atgtaattaa 20 1187 20 DNA Homo sapiens 1187 atatagtttc gtcattcatc 20 1188 20 DNA Homo sapiens 1188 tacattgccc atgtaattaa 20 1189 20 DNA Homo sapiens 1189 atatagtttc gtcattcatc 20 1190 20 DNA Homo sapiens 1190 agatagtttg gtcattcatc 20 1191 20 DNA Homo sapiens 1191 agatagtttc gtcattcatc 20 1192 20 DNA Homo sapiens 1192 agatagtttc ggcattcatc 20 1193 20 DNA Homo sapiens 1193 agatagtttc gtgattcatc 20 1194 21 DNA Homo sapiens 1194 ctcatcatac gtcaaaagcc a 21 1195 21 DNA Homo sapiens 1195 tcatcatacc gcaaaagcca a 21 1196 21 DNA Homo sapiens 1196 catcatacct gaaaagccaa c 21 1197 21 DNA Homo sapiens 1197 atcatacctc gaaagccaac t 21 1198 21 DNA Homo sapiens 1198 tcatacctca gaagccaact a 21 1199 21 DNA Homo sapiens 1199 catacctcaa gagccaacta a 21 1200 21 DNA Homo sapiens 1200 atacctcaaa ggccaactaa c 21 1201 21 DNA Homo sapiens 1201 tacctcaaaa gccaactaac c 21 1202 21 DNA Homo sapiens 1202 acctcaaaag gcaactaacc a 21 1203 21 DNA Homo sapiens 1203 cctcaaaagc gaactaacca a 21 1204 21 DNA Homo sapiens 1204 ctcaaaagcc gactaaccaa c 21 1205 21 DNA Homo sapiens 1205 tcaaaagcca gctaaccaac c 21 1206 21 DNA Homo sapiens 1206 caaaagccaa gtaaccaacc a 21 1207 21 DNA Homo sapiens 1207 aaaagccaac gaaccaacca a 21 1208 21 DNA Homo sapiens 1208 aaagccaact gaccaaccaa t 21 1209 20 DNA Homo sapiens 1209 tacattgccc atgtaattaa 20 1210 20 DNA Homo sapiens 1210 atatagtttc gtcattcatc 20 1211 20 DNA Homo sapiens 1211 tacattgccc atgtaattaa 20 1212 20 DNA Homo sapiens 1212 atatagtttc gtcattcatc 20 1213 20 DNA Homo sapiens 1213 agatagtttg gtcattcatc 20 1214 20 DNA Homo sapiens 1214 agatagtttc gtcattcatc 20 1215 20 DNA Homo sapiens 1215 agatagtttc ggcattcatc 20 1216 20 DNA Homo sapiens 1216 agatagtttc gtgattcatc 20 1217 21 DNA Homo sapiens 1217 cctcatcata cctcaaaagc c 21 1218 20 DNA Homo sapiens 1218 atatagtttc gtcattcatc 20 1219 20 DNA Homo sapiens 1219 tacattgccc atgtaattaa 20 1220 20 DNA Homo sapiens 1220 atatagtttc gtcattcatc 20 1221 20 DNA Homo sapiens 1221 tacattgccc atgtaattaa 20 1222 20 DNA Homo sapiens 1222 agatagtttc gtcattcatc 20 1223 20 DNA Homo sapiens 1223 agatagtttc ctcattcatc 20 1224 20 DNA Homo sapiens 1224 agatagtttc gccattcatc 20 1225 20 DNA Homo sapiens 1225 agatagtttc gtcattcatc 20 1226 21 DNA Homo sapiens 1226 ctcatcatac ctcaaaagcc a 21 1227 21 DNA Homo sapiens 1227 tcatcatacc ccaaaagcca a 21 1228 21 DNA Homo sapiens 1228 catcatacct caaaagccaa c 21 1229 21 DNA Homo sapiens 1229 atcatacctc caaagccaac t 21 1230 21 DNA Homo sapiens 1230 tcatacctca caagccaact a 21 1231 21 DNA Homo sapiens 1231 catacctcaa cagccaacta a 21 1232 21 DNA Homo sapiens 1232 atacctcaaa cgccaactaa c 21 1233 21 DNA Homo sapiens 1233 tacctcaaaa cccaactaac c 21 1234 21 DNA Homo sapiens 1234 acctcaaaag ccaactaacc a 21 1235 21 DNA Homo sapiens 1235 cctcaaaagc caactaacca a 21 1236 21 DNA Homo sapiens 1236 ctcaaaagcc cactaaccaa c 21 1237 21 DNA Homo sapiens 1237 tcaaaagcca cctaaccaac c 21 1238 21 DNA Homo sapiens 1238 caaaagccaa ctaaccaacc a 21 1239 21 DNA Homo sapiens 1239 aaaagccaac caaccaacca a 21 1240 21 DNA Homo sapiens 1240 aaagccaact caccaaccaa t 21 1241 20 DNA Homo sapiens 1241 atatagtttc gtcattcatc 20 1242 20 DNA Homo sapiens 1242 tacattgccc atgtaattaa 20 1243 20 DNA Homo sapiens 1243 atatagtttc gtcattcatc 20 1244 20 DNA Homo sapiens 1244 tacattgccc atgtaattaa 20 1245 20 DNA Homo sapiens 1245 agatagtttc gtcattcatc 20 1246 20 DNA Homo sapiens 1246 agatagtttc ctcattcatc 20 1247 20 DNA Homo sapiens 1247 agatagtttc gccattcatc 20 1248 20 DNA Homo sapiens 1248 agatagtttc gtcattcatc 20 1249 21 DNA Homo sapiens 1249 cctcatcata actcaaaagc c 21 1250 20 DNA Homo sapiens 1250 tacattgccc atgtaattaa 20 1251 20 DNA Homo sapiens 1251 atatagtttc gtcattcatc 20 1252 20 DNA Homo sapiens 1252 tacattgccc atgtaattaa 20 1253 20 DNA Homo sapiens 1253 atatagtttc gtcattcatc 20 1254 20 DNA Homo sapiens 1254 agatagttta gtcattcatc 20 1255 20 DNA Homo sapiens 1255 agatagtttc atcattcatc 20 1256 20 DNA Homo sapiens 1256 agatagtttc gacattcatc 20 1257 20 DNA Homo sapiens 1257 agatagtttc gtaattcatc 20 1258 21 DNA Homo sapiens 1258 ctcatcatac atcaaaagcc a 21 1259 21 DNA Homo sapiens 1259 tcatcatacc acaaaagcca a 21 1260 21 DNA Homo sapiens 1260 catcatacct aaaaagccaa c 21 1261 21 DNA Homo sapiens 1261 atcatacctc aaaagccaac t 21 1262 21 DNA Homo sapiens 1262 tcatacctca aaagccaact a 21 1263 21 DNA Homo sapiens 1263 catacctcaa aagccaacta a 21 1264 21 DNA Homo sapiens 1264 atacctcaaa agccaactaa c 21 1265 21 DNA Homo sapiens 1265 tacctcaaaa accaactaac c 21 1266 21 DNA Homo sapiens 1266 acctcaaaag acaactaacc a 21 1267 21 DNA Homo sapiens 1267 cctcaaaagc aaactaacca a 21 1268 21 DNA Homo sapiens 1268 ctcaaaagcc aactaaccaa c 21 1269 21 DNA Homo sapiens 1269 tcaaaagcca actaaccaac c 21 1270 21 DNA Homo sapiens 1270 caaaagccaa ataaccaacc a 21 1271 21 DNA Homo sapiens 1271 aaaagccaac aaaccaacca a 21 1272 21 DNA Homo sapiens 1272 aaagccaact aaccaaccaa t 21 1273 20 DNA Homo sapiens 1273 tacattgccc atgtaattaa 20 1274 20 DNA Homo sapiens 1274 atatagtttc gtcattcatc 20 1275 20 DNA Homo sapiens 1275 tacattgccc atgtaattaa 20 1276 20 DNA Homo sapiens 1276 atatagtttc gtcattcatc 20 1277 20 DNA Homo sapiens 1277 agatagttta gtcattcatc 20 1278 20 DNA Homo sapiens 1278 agatagtttc atcattcatc 20 1279 20 DNA Homo sapiens 1279 agatagtttc gacattcatc 20 1280 20 DNA Homo sapiens 1280 agatagtttc gtaattcatc 20 1281 39 DNA Homo sapiens 1281 gttttcccag tcacgacttg gttggttatt agagggtgg 39 1282 38 DNA Homo sapiens 1282 aaacagctat gaccatgacc ataaccaacc aatcaacc 38 1283 144 DNA Homo sapiens 1283 ctggctggtc accagagggt ggggcggacc gagtgcgctc ggcggctgcg gagaggggta 60 gagcaggcag cgggcggcgg ggagcagcat ggagccggcg gcggggagca gcatggagcc 120 ttcggctgac tggctggcca cggc 144 1284 18 DNA Homo sapiens 1284 ttagaggatt tgagggat 18 1285 18 DNA Homo sapiens 1285 aaaactccat actactcc 18 1286 60 DNA Homo sapiens 1286 cttggctgtc ccagaatgca agaagcccag acggaaaccg tagctgccct ggtaggtttt 60 1287 20 DNA Homo sapiens 1287 tatatcaaag cagtaagtag 20 1288 90 DNA Homo sapiens 1288 ccaccctcta ataaccaacc aacccctcct ctttcttcct ccaatactaa caaaaaaacc 60 ccctccaacc ctatccctca aatcctctaa 90 1289 90 DNA Homo sapiens 1289 gtgtgtttgg tggttgcgga gagggggaga gtaggtagtg ggtggtgggg agtagtatgg 60 agttggtggt ggggagtagt atggagtttt 90 1290 100 DNA Homo sapiens 1290 ttagaggatt tgagggatag ggttggaggg ggtttttttg ttagtattgg aggaagaaag 60 aggaggggtt ggttggttat tagagggtgg ggtggattgt 100 1291 100 DNA Homo sapiens 1291 aaaactccat actactcccc accaccaact ccatactact ccccaccacc cactacctac 60 tctccccctc tccgcaacca ccaaacacac acaatccacc 100 

What is claimed is:
 1. A method for the analysis of chemical modification of DNA comprising the steps of: obtaining a sample of DNA to be analyzed; treating the DNA with one or more chemical reagents that result in different base sequences depending upon the presence or absence of the modification of interest; and determining a portion of the base sequence of the resulting DNA.
 2. The method recited in claim 1, wherein the chemical modification of interest is methylation.
 3. The method recited in claim 1, wherein the chemical modification of interest is methylation of cytosines.
 4. The method recited in claim 1, wherein the chemical modification of interest is methylation of cytosines in CpG dinucleotides.
 5. The method recited in claim 1, wherein the chemical modification of interest is methylation at the position of carbon 5 of cytosines.
 6. The method recited in claim 1, wherein the chemical modification of interest is methylation of CpG dinucleotides within the promoter regions of one or more genes.
 7. The method recited in claim 1, wherein the chemical modification of interest is methylation of CpG dinucleotides within the promoter regions of one or more tumor suppressor genes.
 8. The method recited in claim 1, wherein the chemical modification of interest is methylation of CpG dinucleotides within the promoter regions of the tumor suppressor gene p16.
 9. The method recited in claim 1, wherein the DNA is obtained from mammalian cells.
 10. The method recited in claim 3, wherein the DNA is treated with reagents that convert unmethylated cytosines to deoxyuridines and leave methylated cytosines unchanged.
 11. The method recited in claim 3, wherein the chemical reagents comprise bisulfite.
 12. The method recited in claim 1, wherein part of the base sequence is determined by binding to an array comprising one or more probe molecules.
 13. The method recited in claim 1, wherein the parts of the sequence that are determined comprise the base positions of potential modification.
 14. The method recited in claim 12, wherein the probe molecules are DNA.
 15. The method recited in claim 12, wherein the probe molecules comprise RNA, peptides, minor groove-binding polyamides, PNA, LNA, or 2′-O-methyl nucleic acid.
 16. The method recited in claim 12, wherein the probe molecules comprise oligonucleotides.
 17. The method recited in claim 16, wherein the probes comprise at least two oligonucleotides for every site in the sample to be analyzed.
 18. The method recited in claim 12, wherein the probe molecules are immobilized on a solid substrate.
 19. The method recited in claim 18, wherein the probe molecules are synthesized off of the array and subsequently deposited to the surface.
 20. The method recited in claim 18, wherein the probes are synthesized directly on the surface of the array.
 21. The method recited in claim 18, wherein the probes are synthesized by light-directed chemistry.
 22. The method recited in claim 21, wherein the probes are synthesized using a digital micromirror array.
 23. The method recited in claim 13, wherein the number of positions probed with a single array is greater than ten.
 24. The method recited in claim 13, wherein the number of positions probed with a single array is greater than
 100. 25. The method recited in claim 13, wherein the number of positions probed with a single array is greater than
 1000. 26. The method recited in claim 13, wherein the number of positions probed with a single array is greater than
 10000. 27. The method recited in claim 13, wherein the number of positions probed with a single array is greater than
 100000. 28. The method recited in claim 1, wherein the part of the DNA for which modification is to be analyzed is determined by an automated search of a sequence database.
 29. The method recited in claim 12, wherein the probe molecules are designed or selected by automated computational methods.
 30. The method recited in claim 12, wherein binding is detected by fluorescence.
 31. The method recited in claim 30, wherein the DNA to be applied to the array is labeled with a fluorescent dye.
 32. The method recited in claim 31, wherein the fluorescent dye comprises a Cy family dye.
 33. The method recited in claim 31, wherein a reference sample is labeled with a first dye and one or more samples to be analyzed are labeled with one or more second dyes.
 34. The method recited in claim 33, wherein the reference sample is one for which the presence or absence of the modification of interest is known at each position of interest.
 35. The method recited in claim 33, wherein the reference sample is from cells of a reference tissue.
 36. The method recited in claim 33, wherein the reference sample has not been treated with chemical reagents that result in different base sequences depending upon the presence or absence of the modification of interest.
 37. An array of one or more probes synthesized on a solid support wherein the probes are controlled for methylation state and detect one or more sites of methylation in a sample.
 38. The array recited in claim 37, wherein the probes are complementary to the sites of methylation to be detected in the sample.
 39. The array recited in claim 37, wherein the methylation site of interest consists of guanine.
 40. The array recited in claim 37, wherein the methylation site of interest consists of adenosine.
 41. The array recited in claim 37 further comprising one or more complementary nucleic acid sequences bound to one or more of the probes.
 42. The array recited in claim 41, wherein the complementary nucleic acid sequence further comprises a fluorescent marker.
 43. The array recited in claim 37, wherein the sample is DNA.
 44. The array recited in claim 37, wherein the probe is selected from the group consisting of DNA, RNA, peptides, oligonucleotides, minor-groove binding polyamides, peptide nucleic acids, locked nucleic acids, 2′-O-methyl nucleic acids, and variations and combinations thereof.
 45. The array recited in claim 37, wherein the probes are nucleic acid sequences of about 15 to about 30 bases in length.
 46. A method for generating DNA probe sequences comprising the steps: inputing a nucleic acid sequence in the 3-prime to 5-prime direction; converting the sequence to account for chemical modification; generating the complimentary sequence to the converted sequence in the 3-prime to 5-prime direction; generating a first parent probe by choosing a first starting position on the complementary sequence and an first ending position on the complementary sequence; generating a second parent probe by moving the first starting and first ending position one base unit in the same direction.
 47. The method recited in claim 46, wherein the inputing is accomplished with a computer.
 48. The method recited in claim 46, wherein the chemical modification comprises treatment with sodium bisulfite.
 49. The method recited in claim 46, wherein the first starting position and the first ending position are separated by about 15 nucleic acid bases.
 50. The method recited in claim 46, wherein the first starting position and the first ending position are separated by from about 15 nucleic acid bases to about 30 nucleic acid bases.
 51. The method recited in claim 46 further comprising the step of filtering the parent probes to remove probes that are unsuitable for re-sequencing analysis.
 52. The method recited in claim 51, wherein the filtering is based on low sequence complexity.
 53. The method recited in claim 46 further comprising the step of using the first and second parent probes to generate additional probes by changing the nucleic acid nearest the midpoint to create a probe not already generated.
 54. The method recited in claim 46 further comprising the step of outputting the parent probes generated to a computer file.
 55. A method for generating DNA probe sequences comprising the steps: inputing a nucleic acid sequence in the 3-prime to 5-prime direction; converting the sequence to account for chemical modification; generating the complimentary sequence to the converted sequence in the 3-prime to 5-prime direction; locating one or more CpG dinucleotide regions within the complementary sequence; generating one or more first probes by identifying sequences that have at least one nucleic acid on each end of the CpG dinucleotide regions.
 56. The method recited in claim 55, wherein the inputing is accomplished with a computer.
 57. The method recited in claim 55, wherein the chemical modification comprises treatment with sodium bisulfite.
 58. The method recited in claim 55, wherein length of the probe is about 15 nucleic acid bases.
 59. The method recited in claim 55, wherein the length of the probe is from about 15 nucleic acid bases to about 30 nucleic acid bases.
 60. The method recited in claim 55 further comprising the step of filtering the parent probes to remove probes that are unsuitable for re-sequencing analysis.
 61. The method recited in claim 55 further comprising the step of using the first probes to generate additional probes by changing the nucleic acid nearest the midpoint to create a probe not already generated.
 60. The method recited in claim 55 further comprising the step of outputting the parent probes generated to a computer file.
 61. An array with the DNA probe sequences of claim
 55. 62. A method of preparing a probe for the analysis of chemical modifications of DNA comprising the steps of: inputing a sample sequence as a sequence file into a computer; converting the sequence file; and generating a complementary sequence of the converted sequence file.
 63. The method recited in claim 62, wherein the sample sequence is selected from the group consisting of DNA, RNA, peptides, oligonucleotides, minor-groove binding polyamides, peptide nucleic acids, locked nucleic acids, 2′-O-methyl nucleic acids, and variations and combinations thereof.
 64. The method recited in claim 62, wherein the inputing of the sample sequence is in the five prime to three prime direction.
 65. The method recited in claim 62, wherein the sequence file is converted to account for a chemical modification of the sample sequence.
 66. The method recited in claim 62, wherein the complimentary sequence is generated in the five prime to three prime direction.
 67. The method recited in claim 62 further comprises creating a parent probe list from the complementary sequence by standard re-sequencing and querying every position of the complemetary sequence.
 68. The method recited in claim 67, wherein the parent probe list is filtered to remove unsuitable probes and is used to create a daughter list of probes containing one or more single polymorphisms at every position of each of the parent probes.
 69. The method recited in claim 68, wherein a probe set is created that consists of all possible partners for each position and polymorphism. 